Metalloid

Template:Short description Template:Periodic table (metalloid) Template:Sidebar periodic table A metalloid is a chemical element which has a preponderance of properties in between, or that are a mixture of, those of metals and nonmetals. The word metalloid comes from the Latin metallum ("metal") and the Greek oeides ("resembling in form or appearance").<ref>Oxford English Dictionary 1989, 'metalloid'; Gordh, Gordh & Headrick 2003, p. 753</ref> There is no standard definition of a metalloid and no complete agreement on which elements are metalloids. Despite the lack of specificity, the term remains in use in the literature.

The six commonly recognised metalloids are boron, silicon, germanium, arsenic, antimony and tellurium. Five elements are less frequently so classified: carbon, aluminium, selenium, polonium and astatine. On a standard periodic table, all eleven elements are in a diagonal region of the p-block extending from boron at the upper left to astatine at lower right. Some periodic tables include a dividing line between metals and nonmetals, and the metalloids may be found close to this line.

Typical metalloids have a metallic appearance, may be brittle and are only fair conductors of electricity. They can form alloys with metals, and many of their other physical properties and chemical properties are intermediate between those of metallic and nonmetallic elements. They and their compounds are used in alloys, biological agents, catalysts, flame retardants, glasses, optical storage and optoelectronics, pyrotechnics, semiconductors, and electronics.

The term metalloid originally referred to nonmetals. Its more recent meaning, as a category of elements with intermediate or hybrid properties, became widespread in 1940–1960. Metalloids are sometimes called semimetals, a practice that has been discouraged,<ref name=Atkins2010p20/> as the term semimetal has a more common usage as a specific kind of electronic band structure of a substance. In this context, only arsenic and antimony are semimetals, and commonly recognised as metalloids.

DefinitionsEdit

Template:See also

Judgment-basedEdit

A metalloid is an element that possesses a preponderance of properties in between, or that are a mixture of, those of metals and nonmetals, and which is therefore hard to classify as either a metal or a nonmetal. This is a generic definition that draws on metalloid attributes consistently cited in the literature.Template:Refn Difficulty of categorisation is a key attribute. Most elements have a mixture of metallic and nonmetallic properties,<ref name=Hopkins>Hopkins & Bailar 1956, p. 458</ref> and can be classified according to which set of properties is more pronounced.<ref>Glinka 1965, p. 77</ref>Template:Refn Only the elements at or near the margins, lacking a sufficiently clear preponderance of either metallic or nonmetallic properties, are classified as metalloids.<ref>Tyler Miller 1987, p. 59</ref>

Boron, silicon, germanium, arsenic, antimony, and tellurium are commonly recognised as metalloids.<ref>Goldsmith 1982, p. 526; Kotz, Treichel & Weaver 2009, p. 62; Bettelheim et al. 2010, p. 46</ref>Template:Refn Depending on the author, one or more from selenium, polonium, or astatine are sometimes added to the list.<ref>Hawkes 2001, p. 1686; Segal 1989, p. 965; McMurray & Fay 2009, p. 767</ref> Boron sometimes is excluded, by itself, or with silicon.<ref>Bucat 1983, p. 26; Brown c. 2007</ref> Sometimes tellurium is not regarded as a metalloid.<ref name="Swift1962,100">Swift & Schaefer 1962, p. 100</ref> The inclusion of antimony, polonium, and astatine as metalloids has been questioned.<ref>Hawkes 2001, p. 1686; Hawkes 2010; Holt, Rinehart & Wilson c. 2007</ref>

Other elements are occasionally classified as metalloids. These elements include<ref>Dunstan 1968, pp. 310, 409. Dunstan lists Be, Al, Ge (maybe), As, Se (maybe), Sn, Sb, Te, Pb, Bi, and Po as metalloids (pp. 310, 323, 409, 419).</ref> hydrogen,<ref>Tilden 1876, pp. 172, 198–201; Smith 1994, p. 252; Bodner & Pardue 1993, p. 354</ref> beryllium,<ref>Bassett et al. 1966, p. 127</ref> nitrogen,<ref name=rausch>Rausch 1960</ref> phosphorus,<ref>Thayer 1977, p. 604; Warren & Geballe 1981; Masters & Ela 2008, p. 190</ref> sulfur,<ref>Warren & Geballe 1981; Chalmers 1959, p. 72; US Bureau of Naval Personnel 1965, p. 26</ref> zinc,<ref>Siebring 1967, p. 513</ref> gallium,<ref>Wiberg 2001, p. 282</ref> tin, iodine,<ref>Rausch 1960; Friend 1953, p. 68</ref> lead,<ref>Murray 1928, p. 1295</ref> bismuth,<ref name="Swift1962,100"/> and radon.<ref>Hampel & Hawley 1966, p. 950; Stein 1985; Stein 1987, pp. 240, 247–48</ref> The term metalloid has also been used for elements that exhibit metallic lustre and electrical conductivity, and that are amphoteric, such as arsenic, antimony, vanadium, chromium, molybdenum, tungsten, tin, lead, and aluminium.<ref>Hatcher 1949, p. 223; Secrist & Powers 1966, p. 459</ref> The p-block metals,<ref>Taylor 1960, p. 614</ref> and nonmetals (such as carbon or nitrogen) that can form alloys with metals<ref>Considine & Considine 1984, p. 568; Cegielski 1998, p. 147; The American heritage science dictionary 2005, p. 397</ref> or modify their properties<ref>Woodward 1948, p. 1</ref> have also occasionally been considered as metalloids.

Criteria-basedEdit

No widely accepted definition of a metalloid exists, nor any division of the periodic table into metals, metalloids, and nonmetals;<ref>Goldsmith 1982, p. 526; Hawkes 2001, p. 1686</ref> Hawkes<ref name=H1687>Hawkes 2001, p. 1687</ref> questioned the feasibility of establishing a specific definition, noting that anomalies can be found in several attempted constructs. Classifying an element as a metalloid has been described by Sharp<ref name="Sharp1981">Sharp 1981, p. 299</ref> as "arbitrary".

The number and identities of metalloids depend on what classification criteria are used. Emsley<ref>Emsley 1971, p. 1</ref> recognised four metalloids (germanium, arsenic, antimony, and tellurium); James et al.<ref>James et al. 2000, p. 480</ref> listed twelve (Emsley's plus boron, carbon, silicon, selenium, bismuth, polonium, moscovium, and livermorium). On average, seven elements are included in such lists; individual classification arrangements tend to share common ground and vary in the ill-defined<ref>Chatt 1951, p. 417 "The boundary between metals and metalloids is indefinite ..."; Burrows et al. 2009, p. 1192: "Although the elements are conveniently described as metals, metalloids, and nonmetals, the transitions are not exact ..."</ref> margins.Template:RefnTemplate:Refn

A single quantitative criterion such as electronegativity is commonly used,<ref>Rochow 1966, pp. 1, 4–7</ref> metalloids having electronegativity values from 1.8 or 1.9 to 2.2.<ref>Rochow 1977, p. 76; Mann et al. 2000, p. 2783</ref> Further examples include packing efficiency (the fraction of volume in a crystal structure occupied by atoms) and the Goldhammer–Herzfeld criterion ratio.<ref>Askeland, Phulé & Wright 2011, p. 69</ref> The commonly recognised metalloids have packing efficiencies of between 34% and 41%.Template:Refn The Goldhammer–Herzfeld ratio, roughly equal to the cube of the atomic radius divided by the molar volume,<ref>Edwards & Sienko 1983, p. 693</ref>Template:Refn is a simple measure of how metallic an element is, the recognised metalloids having ratios from around 0.85 to 1.1 and averaging 1.0.<ref>Edwards & Sienko 1983, p. 695; Edwards et al. 2010</ref>Template:Refn Other authors have relied on, for example, atomic conductanceTemplate:Refn<ref>Hill & Holman 2000, p. 160. They characterise metalloids (in part) on the basis that they are "poor conductors of electricity with atomic conductance usually less than 10⁻³ but greater than 10⁻⁵ ohm⁻¹ cm⁻⁴".</ref> or bulk coordination number.<ref>Bond 2005, p. 3: "One criterion for distinguishing semi-metals from true metals under normal conditions is that the bulk coordination number of the former is never greater than eight, while for metals it is usually twelve (or more, if for the body-centred cubic structure one counts next-nearest neighbours as well)."</ref>

Jones, writing on the role of classification in science, observed that "[classes] are usually defined by more than two attributes".<ref>Jones 2010, p. 169</ref> Masterton and Slowinski<ref>Masterton & Slowinski 1977, p. 160 list B, Si, Ge, As, Sb, and Te as metalloids, and comment that Po and At are ordinarily classified as metalloids but add that this is arbitrary as so little is known about them.</ref> used three criteria to describe the six elements commonly recognised as metalloids: metalloids have ionization energies around 200 kcal/mol (837 kJ/mol) and electronegativity values close to 2.0. They also said that metalloids are typically semiconductors, though antimony and arsenic (semimetals from a physics perspective) have electrical conductivities approaching those of metals. Selenium and polonium are suspected as not in this scheme, while astatine's status is uncertain.Template:Refn

In this context, Vernon proposed that a metalloid is a chemical element that, in its standard state, has (a) the electronic band structure of a semiconductor or a semimetal; and (b) an intermediate first ionization potential "(say 750−1,000 kJ/mol)"; and (c) an intermediate electronegativity (1.9–2.2).<ref>Vernon 2013, p. 1703</ref>

Periodic table territoryEdit

LocationEdit

Metalloids lie on either side of the dividing line between metals and nonmetals. This can be found, in varying configurations, on some periodic tables. Elements to the lower left of the line generally display increasing metallic behaviour; elements to the upper right display increasing nonmetallic behaviour.<ref name="Hamm 1969, p.653"/> When presented as a regular stairstep, elements with the highest critical temperature for their groups (Li, Be, Al, Ge, Sb, Po) lie just below the line.<ref>Horvath 1973, p. 336</ref>

The diagonal positioning of the metalloids represents an exception to the observation that elements with similar properties tend to occur in vertical groups.<ref name="Gray91">Gray 2009, p. 9</ref> A related effect can be seen in other diagonal similarities between some elements and their lower right neighbours, specifically lithium-magnesium, beryllium-aluminium, and boron-silicon. Rayner-Canham<ref name="Rayner2011">Rayner-Canham 2011</ref> has argued that these similarities extend to carbon-phosphorus, nitrogen-sulfur, and into three d-block series.

This exception arises due to competing horizontal and vertical trends in the nuclear charge. Going along a period, the nuclear charge increases with atomic number as do the number of electrons. The additional pull on outer electrons as nuclear charge increases generally outweighs the screening effect of having more electrons. With some irregularities, atoms therefore become smaller, ionization energy increases, and there is a gradual change in character, across a period, from strongly metallic, to weakly metallic, to weakly nonmetallic, to strongly nonmetallic elements.<ref>Booth & Bloom 1972, p. 426; Cox 2004, pp. 17, 18, 27–28; Silberberg 2006, pp. 305–13</ref> Going down a main group, the effect of increasing nuclear charge is generally outweighed by the effect of additional electrons being further away from the nucleus. Atoms generally become larger, ionization energy falls, and metallic character increases.<ref>Cox 2004, pp. 17–18, 27–28; Silberberg 2006, pp. 305–13</ref> The net effect is that the location of the metal–nonmetal transition zone shifts to the right in going down a group,<ref name=Gray91/> and analogous diagonal similarities are seen elsewhere in the periodic table, as noted.<ref>Rodgers 2011, pp. 232–33; 240–41</ref>

Alternative treatmentsEdit

Elements bordering the metal–nonmetal dividing line are not always classified as metalloids, noting a binary classification can facilitate the establishment of rules for determining bond types between metals and nonmetals.<ref name=roher>Roher 2001, pp. 4–6</ref> In such cases, the authors concerned focus on one or more attributes of interest to make their classification decisions, rather than being concerned about the marginal nature of the elements in question. Their considerations may or not be made explicit and may, at times, seem arbitrary.<ref name=Sharp1981/>Template:Refn Metalloids may be grouped with metals;<ref>Tyler 1948, p. 105; Reilly 2002, pp. 5–6</ref> or regarded as nonmetals;<ref>Hampel & Hawley 1976, p. 174;</ref> or treated as a sub-category of nonmetals.<ref>Goodrich 1844, p. 264; The Chemical News 1897, p. 189; Hampel & Hawley 1976, p. 191; Lewis 1993, p. 835; Hérold 2006, pp. 149–50</ref>Template:Refn Other authors have suggested classifying some elements as metalloids "emphasizes that properties change gradually rather than abruptly as one moves across or down the periodic table".<ref name=brown>Brown & Holme 2006, p. 57</ref> Some periodic tables distinguish elements that are metalloids and display no formal dividing line between metals and nonmetals. Metalloids are instead shown as occurring in a diagonal band<ref>Wiberg 2001, p. 282; Simple Memory Art c. 2005</ref> or diffuse region.<ref>Chedd 1969, pp. 12–13</ref> The key consideration is to explain the context for the taxonomy in use.

PropertiesEdit

Metalloids usually look like metals but behave largely like nonmetals. Physically, they are shiny, brittle solids with intermediate to relatively good electrical conductivity and the electronic band structure of a semimetal or semiconductor. Chemically, they mostly behave as (weak) nonmetals, have intermediate ionization energies and electronegativity values, and amphoteric or weakly acidic oxides. Most of their other physical and chemical properties are intermediate in nature.

Compared to metals and nonmetalsEdit

{{#invoke:Labelled list hatnote|labelledList|Main article|Main articles|Main page|Main pages}} Characteristic properties of metals, metalloids, and nonmetals are summarized in the table.<ref>Kneen, Rogers & Simpson, 1972, p. 263. Columns 2 and 4 are sourced from this reference unless otherwise indicated.</ref> Physical properties are listed in order of ease of determination; chemical properties run from general to specific, and then to descriptive.

The above table reflects the hybrid nature of metalloids. The properties of form, appearance, and behaviour when mixed with metals are more like metals. Elasticity and general chemical behaviour are more like nonmetals. Electrical conductivity, band structure, ionization energy, electronegativity, and oxides are intermediate between the two.

Common applicationsEdit

The focus of this section is on the recognised metalloids. Elements less often recognised as metalloids are ordinarily classified as either metals or nonmetals; some of these are included here for comparative purposes.

Metalloids are too brittle to have any structural uses in their pure forms.<ref>Russell & Lee 2005, pp. 421, 423; Gray 2009, p. 23</ref> They and their compounds are used in alloys, biological agents (toxicological, nutritional, and medicinal), catalysts, flame retardants, glasses (oxide and metallic), optical storage media and optoelectronics, pyrotechnics, semiconductors, and electronics.Template:Refn

AlloysEdit

Writing early in the history of intermetallic compounds, the British metallurgist Cecil Desch observed that "certain non-metallic elements are capable of forming compounds of distinctly metallic character with metals, and these elements may therefore enter into the composition of alloys". He associated silicon, arsenic, and tellurium, in particular, with the alloy-forming elements.<ref>Desch 1914, p. 86</ref> Phillips and Williams<ref>Phillips & Williams 1965, p. 620</ref> suggested that compounds of silicon, germanium, arsenic, and antimony with B metals, "are probably best classed as alloys".

Among the lighter metalloids, alloys with transition metals are well-represented. Boron can form intermetallic compounds and alloys with such metals of the composition M_nB, if n > 2.<ref>Van der Put 1998, p. 123</ref> Ferroboron (15% boron) is used to introduce boron into steel; nickel-boron alloys are ingredients in welding alloys and case hardening compositions for the engineering industry. Alloys of silicon with iron and with aluminium are widely used by the steel and automotive industries, respectively. Germanium forms many alloys, most importantly with the coinage metals.<ref>Klug & Brasted 1958, p. 199</ref>

The heavier metalloids continue the theme. Arsenic can form alloys with metals, including platinum and copper;<ref>Good et al. 1813</ref> it is also added to copper and its alloys to improve corrosion resistance<ref>Sequeira 2011, p. 776</ref> and appears to confer the same benefit when added to magnesium.<ref>Gary 2013</ref> Antimony is well known as an alloy-former, including with the coinage metals. Its alloys include pewter (a tin alloy with up to 20% antimony) and type metal (a lead alloy with up to 25% antimony).<ref>Russell & Lee 2005, pp. 405–06; 423–34</ref> Tellurium readily alloys with iron, as ferrotellurium (50–58% tellurium), and with copper, in the form of copper tellurium (40–50% tellurium).<ref>Davidson & Lakin 1973, p. 627</ref> Ferrotellurium is used as a stabilizer for carbon in steel casting.<ref>Wiberg 2001, p. 589</ref> Of the non-metallic elements less often recognised as metalloids, selenium – in the form of ferroselenium (50–58% selenium) – is used to improve the machinability of stainless steels.<ref>Greenwood & Earnshaw 2002, p. 749; Schwartz 2002, p. 679</ref>

Biological agentsEdit

All six of the elements commonly recognised as metalloids have toxic, dietary or medicinal properties.<ref>Řezanka & Sigler 2008; Sekhon 2012</ref> Arsenic and antimony compounds are especially toxic; boron, silicon, and possibly arsenic, are essential trace elements. Boron, silicon, arsenic, and antimony have medical applications, and germanium and tellurium are thought to have potential.

Boron is used in insecticides<ref>Emsley 2001, p. 67</ref> and herbicides.<ref>Zhang et al. 2008, p. 360</ref> It is an essential trace element.<ref name=SLH>Science Learning Hub 2009</ref> As boric acid, it has antiseptic, antifungal, and antiviral properties.<ref>Skinner et al. 1979; Tom, Elden & Marsh 2004, p. 135</ref>

Silicon is present in silatrane, a highly toxic rodenticide.<ref>Büchel 1983, p. 226</ref> Long-term inhalation of silica dust causes silicosis, a fatal disease of the lungs. Silicon is an essential trace element.<ref name=SLH/> Silicone gel can be applied to badly burned patients to reduce scarring.<ref>Emsley 2001, p. 391</ref>

Salts of germanium are potentially harmful to humans and animals if ingested on a prolonged basis.<ref>Schauss 1991; Tao & Bolger 1997</ref> There is interest in the pharmacological actions of germanium compounds but no licensed medicine as yet.<ref>Eagleson 1994, p. 450; EVM 2003, pp. 197‒202</ref>

Arsenic is notoriously poisonous and may also be an essential element in ultratrace amounts.<ref name=Neilsen>Nielsen 1998</ref> During World War I, both sides used "arsenic-based sneezing and vomiting agents…to force enemy soldiers to remove their gas masks before firing mustard or phosgene at them in a second salvo."<ref>MacKenzie 2015, p. 36</ref> It has been used as a pharmaceutical agent since antiquity, including for the treatment of syphilis before the development of antibiotics.<ref name=Jaouen>Jaouen & Gibaud 2010</ref> Arsenic is also a component of melarsoprol, a medicinal drug used in the treatment of human African trypanosomiasis or sleeping sickness. In 2003, arsenic trioxide (under the trade name Trisenox) was re-introduced for the treatment of acute promyelocytic leukaemia, a cancer of the blood and bone marrow.<ref name=Jaouen/> Arsenic in drinking water, which causes lung and bladder cancer, has been associated with a reduction in breast cancer mortality rates.<ref>Smith et al. 2014</ref>

Metallic antimony is relatively non-toxic, but most antimony compounds are poisonous.<ref>Stevens & Klarner, p. 205</ref> Two antimony compounds, sodium stibogluconate and stibophen, are used as antiparasitical drugs.<ref>Sneader 2005, pp. 57–59</ref>

Elemental tellurium is not considered particularly toxic; two grams of sodium tellurate, if administered, can be lethal.<ref>Keall, Martin and Tunbridge 1946</ref> People exposed to small amounts of airborne tellurium exude a foul and persistent garlic-like odour.<ref>Emsley 2001, p. 426</ref> Tellurium dioxide has been used to treat seborrhoeic dermatitis; other tellurium compounds were used as antimicrobial agents before the development of antibiotics.<ref>Oldfield et al. 1974, p. 65; Turner 2011</ref> In the future, such compounds may need to be substituted for antibiotics that have become ineffective due to bacterial resistance.<ref>Ba et al. 2010; Daniel-Hoffmann, Sredni & Nitzan 2012; Molina-Quiroz et al. 2012</ref>

Of the elements less often recognised as metalloids, beryllium and lead are noted for their toxicity; lead arsenate has been extensively used as an insecticide.<ref>Peryea 1998</ref> Sulfur is one of the oldest of the fungicides and pesticides. Phosphorus, sulfur, zinc, selenium, and iodine are essential nutrients, and aluminium, tin, and lead may be.<ref name=Neilsen/> Sulfur, gallium, selenium, iodine, and bismuth have medicinal applications. Sulfur is a constituent of sulfonamide drugs, still widely used for conditions such as acne and urinary tract infections.<ref>Hager 2006, p. 299</ref> Gallium nitrate is used to treat the side effects of cancer;<ref>Apseloff 1999</ref> gallium citrate, a radiopharmaceutical, facilitates imaging of inflamed body areas.<ref>Trivedi, Yung & Katz 2013, p. 209</ref> Selenium sulfide is used in medicinal shampoos and to treat skin infections such as tinea versicolor.<ref>Emsley 2001, p. 382; Burkhart, Burkhart & Morrell 2011</ref> Iodine is used as a disinfectant in various forms. Bismuth is an ingredient in some antibacterials.<ref>Thomas, Bialek & Hensel 2013, p. 1</ref>

CatalystsEdit

Boron trifluoride and trichloride are used as homogeneous catalysts in organic synthesis and electronics; the tribromide is used in the manufacture of diborane.<ref>Perry 2011, p. 74</ref> Non-toxic boron ligands could replace toxic phosphorus ligands in some transition metal catalysts.<ref>UCR Today 2011; Wang & Robinson 2011; Kinjo et al. 2011</ref> Silica sulfuric acid (SiO₂OSO₃H) is used in organic reactions.<ref>Kauthale et al. 2015</ref> Germanium dioxide is sometimes used as a catalyst in the production of PET plastic for containers;<ref>Gunn 2014, pp. 188, 191</ref> cheaper antimony compounds, such as the trioxide or triacetate, are more commonly employed for the same purpose<ref>Gupta, Mukherjee & Cameotra 1997, p. 280; Thomas & Visakh 2012, p. 99</ref> despite concerns about antimony contamination of food and drinks.<ref>Muncke 2013</ref> Arsenic trioxide has been used in the production of natural gas, to boost the removal of carbon dioxide, as have selenous acid and tellurous acid.<ref>Mokhatab & Poe 2012, p. 271</ref> Selenium acts as a catalyst in some microorganisms.<ref>Craig, Eng & Jenkins 2003, p. 25</ref> Tellurium, its dioxide, and its tetrachloride are strong catalysts for air oxidation of carbon above 500 °C.<ref>McKee 1984</ref> Graphite oxide can be used as a catalyst in the synthesis of imines and their derivatives.<ref>Hai et al. 2012</ref> Activated carbon and alumina have been used as catalysts for the removal of sulfur contaminants from natural gas.<ref>Kohl & Nielsen 1997, pp. 699–700</ref> Titanium doped aluminium has been suggested as a substitute for noble metal catalysts used in the production of industrial chemicals.<ref>Chopra et al. 2011</ref>

Flame retardantsEdit

Compounds of boron, silicon, arsenic, and antimony have been used as flame retardants. Boron, in the form of borax, has been used as a textile flame retardant since at least the 18th century.<ref>Le Bras, Wilkie & Bourbigot 2005, p. v</ref> Silicon compounds such as silicones, silanes, silsesquioxane, silica, and silicates, some of which were developed as alternatives to more toxic halogenated products, can considerably improve the flame retardancy of plastic materials.<ref>Wilkie & Morgan 2009, p. 187</ref> Arsenic compounds such as sodium arsenite or sodium arsenate are effective flame retardants for wood but have been less frequently used due to their toxicity.<ref>Locke et al. 1956, p. 88</ref> Antimony trioxide is a flame retardant.<ref>Carlin 2011, p. 6.2</ref> Aluminium hydroxide has been used as a wood-fibre, rubber, plastic, and textile flame retardant since the 1890s.<ref>Evans 1993, pp. 257–28</ref> Apart from aluminium hydroxide, use of phosphorus based flame-retardants – in the form of, for example, organophosphates – now exceeds that of any of the other main retardant types. These employ boron, antimony, or halogenated hydrocarbon compounds.<ref>Corbridge 2013, p. 1149</ref>

Glass formationEdit

The oxides B₂O₃, SiO₂, GeO₂, As₂O₃, and Sb₂O₃ readily form glasses. TeO₂ forms a glass but this requires a "heroic quench rate"<ref name=K2002/> or the addition of an impurity; otherwise the crystalline form results.<ref name=K2002>Kaminow & Li 2002, p. 118</ref> These compounds are used in chemical, domestic, and industrial glassware<ref>Deming 1925, pp. 330 (As₂O₃), 418 (B₂O₃; SiO₂; Sb₂O₃); Witt & Gatos 1968, p. 242 (GeO₂)</ref> and optics.<ref>Eagleson 1994, p. 421 (GeO₂); Rothenberg 1976, 56, 118–19 (TeO₂)</ref> Boron trioxide is used as a glass fibre additive,<ref>Geckeler 1987, p. 20</ref> and is also a component of borosilicate glass, widely used for laboratory glassware and domestic ovenware for its low thermal expansion.<ref>Kreith & Goswami 2005, pp. 12–109</ref> Most ordinary glassware is made from silicon dioxide.<ref>Russell & Lee 2005, p. 397</ref> Germanium dioxide is used as a glass fibre additive, as well as in infrared optical systems.<ref>Butterman & Jorgenson 2005, pp. 9–10</ref> Arsenic trioxide is used in the glass industry as a decolourizing and fining agent (for the removal of bubbles),<ref>Shelby 2005, p. 43</ref> as is antimony trioxide.<ref>Butterman & Carlin 2004, p. 22; Russell & Lee 2005, p. 422</ref> Tellurium dioxide finds application in laser and nonlinear optics.<ref>Träger 2007, pp. 438, 958; Eranna 2011, p. 98</ref>

Amorphous metallic glasses are generally most easily prepared if one of the components is a metalloid or "near metalloid" such as boron, carbon, silicon, phosphorus or germanium.<ref>Rao 2002, p. 552; Löffler, Kündig & Dalla Torre 2007, p. 17–11</ref>Template:Refn Aside from thin films deposited at very low temperatures, the first known metallic glass was an alloy of composition Au₇₅Si₂₅ reported in 1960.<ref>Klement, Willens & Duwez 1960; Wanga, Dongb & Shek 2004, p. 45</ref> A metallic glass having a strength and toughness not previously seen, of composition Pd_82.5P₆Si_9.5Ge₂, was reported in 2011.<ref>Demetriou et al. 2011; Oliwenstein 2011</ref>

Phosphorus, selenium, and lead, which are less often recognised as metalloids, are also used in glasses. Phosphate glass has a substrate of phosphorus pentoxide (P₂O₅), rather than the silica (SiO₂) of conventional silicate glasses. It is used, for example, to make sodium lamps.<ref>Karabulut et al. 2001, p. 15; Haynes 2012, pp. 4–26</ref> Selenium compounds can be used both as decolourising agents and to add a red colour to glass.<ref>Schwartz 2002, pp. 679–80</ref> Decorative glassware made of traditional lead glass contains at least 30% lead(II) oxide (PbO); lead glass used for radiation shielding may have up to 65% PbO.<ref>Carter & Norton 2013, p. 403</ref> Lead-based glasses have also been extensively used in electronic components, enamelling, sealing and glazing materials, and solar cells. Bismuth based oxide glasses have emerged as a less toxic replacement for lead in many of these applications.<ref>Maeder 2013, pp. 3, 9–11</ref>

Optical storage and optoelectronicsEdit

Varying compositions of GeSbTe ("GST alloys") and Ag- and In- doped Sb₂Te ("AIST alloys"), being examples of phase-change materials, are widely used in rewritable optical discs and phase-change memory devices. By applying heat, they can be switched between amorphous (glassy) and crystalline states. The change in optical and electrical properties can be used for information storage purposes.<ref>Tominaga 2006, pp. 327–28; Chung 2010, pp. 285–86; Kolobov & Tominaga 2012, p. 149</ref> Future applications for GeSbTe may include, "ultrafast, entirely solid-state displays with nanometre-scale pixels, semi-transparent 'smart' glasses, 'smart' contact lenses, and artificial retina devices."<ref>New Scientist 2014; Hosseini, Wright & Bhaskaran 2014; Farandos et al. 2014</ref>

PyrotechnicsEdit

The recognised metalloids have either pyrotechnic applications or associated properties. Boron and silicon are commonly encountered;<ref name=Kos>Kosanke 2002, p. 110</ref> they act somewhat like metal fuels.<ref>Ellern 1968, pp. 246, 326–27</ref> Boron is used in pyrotechnic initiator compositions (for igniting other hard-to-start compositions), and in delay compositions that burn at a constant rate.<ref name=Conkling82>Conkling & Mocella 2010, p. 82</ref> Boron carbide has been identified as a possible replacement for more toxic barium or hexachloroethane mixtures in smoke munitions, signal flares, and fireworks.<ref>Crow 2011; Mainiero 2014</ref> Silicon, like boron, is a component of initiator and delay mixtures.<ref name=Conkling82/> Doped germanium can act as a variable speed thermite fuel.Template:Refn Arsenic trisulfide As₂S₃ was used in old naval signal lights; in fireworks to make white stars;<ref>Ellern 1968, p. 135; Weingart 1947, p. 9</ref> in yellow smoke screen mixtures; and in initiator compositions.<ref>Conkling & Mocella 2010, p. 83</ref> Antimony trisulfide Sb₂S₃ is found in white-light fireworks and in flash and sound mixtures.<ref>Conkling & Mocella 2010, pp. 181, 213</ref> Tellurium has been used in delay mixtures and in blasting cap initiator compositions.<ref name=Ellern>Ellern 1968, pp. 209–10, 322</ref>

Carbon, aluminium, phosphorus, and selenium continue the theme. Carbon, in black powder, is a constituent of fireworks rocket propellants, bursting charges, and effects mixtures, and military delay fuses and igniters.<ref>Russell 2009, pp. 15, 17, 41, 79–80</ref>Template:Refn Aluminium is a common pyrotechnic ingredient,<ref name=Kos/> and is widely employed for its capacity to generate light and heat,<ref>Ellern 1968, p. 328</ref> including in thermite mixtures.<ref>Conkling & Mocella 2010, p. 171</ref> Phosphorus can be found in smoke and incendiary munitions, paper caps used in toy guns, and party poppers.<ref>Conkling & Mocella 2011, pp. 83–84</ref> Selenium has been used in the same way as tellurium.<ref name=Ellern/>

Semiconductors and electronicsEdit

All the elements commonly recognised as metalloids (or their compounds) have been used in the semiconductor or solid-state electronic industries.<ref>Berger 1997, p. 91; Hampel 1968, passim</ref>

Some properties of boron have limited its use as a semiconductor. It has a high melting point, single crystals are relatively hard to obtain, and introducing and retaining controlled impurities is difficult.<ref>Rochow 1966, p. 41; Berger 1997, pp. 42–43</ref>

Silicon is the leading commercial semiconductor; it forms the basis of modern electronics (including standard solar cells)<ref name=Bom>Bomgardner 2013, p. 20</ref> and information and communication technologies.<ref>Russell & Lee 2005, p. 395; Brown et al. 2009, p. 489</ref> This was despite the study of semiconductors, early in the 20th century, having been regarded as the "physics of dirt" and not deserving of close attention.<ref>Haller 2006, p. 4: "The study and understanding of the physics of semiconductors progressed slowly in the 19th and early 20th centuries ... Impurities and defects ... could not be controlled to the degree necessary to obtain reproducible results. This led influential physicists, including W. Pauli and I. Rabi, to comment derogatorily on the 'Physics of Dirt'."; Hoddeson 2007, pp. 25–34 (29)</ref>

Germanium has largely been replaced by silicon in semiconducting devices, being cheaper, more resilient at higher operating temperatures, and easier to work during the microelectronic fabrication process.<ref name=Russell2005401>Russell & Lee 2005, p. 401; Büchel, Moretto & Woditsch 2003, p. 278</ref> Germanium is still a constituent of semiconducting silicon-germanium "alloys" and these have been growing in use, particularly for wireless communication devices; such alloys exploit the higher carrier mobility of germanium.<ref name=Russell2005401/> The synthesis of gram-scale quantities of semiconducting germanane was reported in 2013. This consists of one-atom thick sheets of hydrogen-terminated germanium atoms, analogous to graphane. It conducts electrons more than ten times faster than silicon and five times faster than germanium, and is thought to have potential for optoelectronic and sensing applications.<ref>Bianco et al. 2013</ref> The development of a germanium-wire based anode that more than doubles the capacity of lithium-ion batteries was reported in 2014.<ref>University of Limerick 2014; Kennedy et al. 2014</ref> In the same year, Lee et al. reported that defect-free crystals of graphene large enough to have electronic uses could be grown on, and removed from, a germanium substrate.<ref>Lee et al. 2014</ref>

Arsenic and antimony are not semiconductors in their standard states. Both form type III-V semiconductors (such as GaAs, AlSb or GaInAsSb) in which the average number of valence electrons per atom is the same as that of Group 14 elements, but they have direct band gaps. These compounds are preferred for optical applications.<ref>Russell & Lee 2005, pp. 421–22, 424</ref> Antimony nanocrystals may enable lithium-ion batteries to be replaced by more powerful sodium ion batteries.<ref>He et al. 2014</ref>

Tellurium, which is a semiconductor in its standard state, is used mainly as a component in type II/VI semiconducting-chalcogenides; these have applications in electro-optics and electronics.<ref>Berger 1997, p. 91</ref> Cadmium telluride (CdTe) is used in solar modules for its high conversion efficiency, low manufacturing costs, and large band gap of 1.44 eV, letting it absorb a wide range of wavelengths.<ref name=Bom/> Bismuth telluride (Bi₂Te₃), alloyed with selenium and antimony, is a component of thermoelectric devices used for refrigeration or portable power generation.<ref>ScienceDaily 2012</ref>

Five metalloids – boron, silicon, germanium, arsenic, and antimony – can be found in cell phones (along with at least 39 other metals and nonmetals).<ref>Reardon 2005; Meskers, Hagelüken & Van Damme 2009, p. 1131</ref> Tellurium is expected to find such use.<ref>The Economist 2012</ref> Of the less often recognised metalloids, phosphorus, gallium (in particular) and selenium have semiconductor applications. Phosphorus is used in trace amounts as a dopant for n-type semiconductors.<ref>Whitten 2007, p. 488</ref> The commercial use of gallium compounds is dominated by semiconductor applications – in integrated circuits, cell phones, laser diodes, light-emitting diodes, photodetectors, and solar cells.<ref>Jaskula 2013</ref> Selenium is used in the production of solar cells<ref>German Energy Society 2008, pp. 43–44</ref> and in high-energy surge protectors.<ref>Patel 2012, p. 248</ref>

Boron, silicon, germanium, antimony, and tellurium,<ref>Moore 2104; University of Utah 2014; Xu et al. 2014</ref> as well as heavier metals and metalloids such as Sm, Hg, Tl, Pb, Bi, and Se,<ref>Yang et al. 2012, p. 614</ref> can be found in topological insulators. These are alloys<ref>Moore 2010, p. 195</ref> or compounds which, at ultracold temperatures or room temperature (depending on their composition), are metallic conductors on their surfaces but insulators through their interiors.<ref>Moore 2011</ref> Cadmium arsenide Cd₃As₂, at about 1 K, is a Dirac-semimetal – a bulk electronic analogue of graphene – in which electrons travel effectively as massless particles.<ref>Liu 2014</ref> These two classes of material are thought to have potential quantum computing applications.<ref>Bradley 2014; University of Utah 2014</ref>

Nomenclature and historyEdit

Derivation and other namesEdit

Several names are sometimes used synonymously although some of these have other meanings that are not necessarily interchangeable: amphoteric element,<ref>Foster 1936, pp. 212–13; Brownlee et al. 1943, p. 293</ref> boundary element,<ref>Calderazzo, Ercoli & Natta 1968, p. 257</ref> half-way element,<ref>Walters 1982, pp. 32–33</ref> near metal,<ref name=tyler>Tyler 1948, p. 105</ref> meta-metal,<ref>Foster & Wrigley 1958, p. 218: "The elements may be grouped into two classes: those that are metals and those that are nonmetals. There is also an intermediate group known variously as metalloids, meta-metals, semiconductors."</ref> semiconductor,<ref>Slade 2006, p. 16</ref> semimetal<ref>Corwin 2005, p. 80</ref> and submetal.<ref>Barsanov & Ginzburg 1974, p. 330</ref> "Amphoteric element" is sometimes used more broadly to include transition metals capable of forming oxyanions, such as chromium and manganese.<ref>Bradbury et al. 1957, pp. 157, 659</ref> "Meta-metal" is sometimes used instead to refer to certain metals (Be, Zn, Cd, Hg, In, Tl, β-Sn, Pb) located just to the left of the metalloids on standard periodic tables.<ref name="Klemm">Klemm 1950, pp. 133–42; Reilly 2004, p. 4</ref> These metals tend to have distorted crystalline structures, electrical conductivity values at the lower end of those of metals, and amphoteric (weakly basic) oxides.<ref>King 2004, pp. 196–98; Ferro & Saccone 2008, p. 233</ref> The names amphoteric element and semiconductor are problematic as some elements referred to as metalloids do not show marked amphoteric behaviour (bismuth, for example)<ref>Lister 1965, p. 54</ref> or semiconductivity (polonium)<ref name="Cotton FA 1999, p.502"/> in their most stable forms.

Origin and usageEdit

{{#invoke:Labelled list hatnote|labelledList|Main article|Main articles|Main page|Main pages}} The origin and usage of the term metalloid is convoluted. The name was popularized by Jöns Berzelius in the early 19th century, but he did not use it in the current meaning, but rather for a diverse group of nonmetal elements.<ref name="b729">Template:Cite book</ref> James Apjohn's "Manual of Metalloids" published in 1864 divided all elements into either metals or metalloids.<ref>Apjohn, J. (1864). Manual of the Metalloids. United Kingdom: Longman.</ref>Template:Rp Since the mid-20th century it has been used to refer to intermediate or borderline chemical elements.<ref name="ReferenceA">Goldsmith 1982, p. 526</ref> The International Union of Pure and Applied Chemistry (IUPAC) previously recommended abandoning the term metalloid, and suggested using the term semimetal instead.<ref>Friend 1953, p. 68; IUPAC 1959, p. 10; IUPAC 1971, p. 11</ref> Despite the recommendation, the term metalloid was increasingly used in the literature in 1970Template:Endash2010, while semimetal remained less popular.<ref name="b729"/> Use of the term semimetal has more recently been discouraged by Atkins et al.<ref name=Atkins2010p20>Atkins et al. 2010, p. 20</ref> as it has a more common meaning that refers to the electronic band structure of a substance rather than the overall classification of an element. The most recent IUPAC publications on nomenclature and terminology do not include any recommendations on the usage of the terms metalloid or semimetal.<ref>IUPAC 2005; IUPAC 2006–</ref>

Elements commonly recognised as metalloidsEdit

Properties noted in this section refer to the elements in their most thermodynamically stable forms under ambient conditions.

BoronEdit

{{#invoke:Labelled list hatnote|labelledList|Main article|Main articles|Main page|Main pages}}

Pure boron is a shiny, silver-grey crystalline solid.<ref>Housecroft & Sharpe 2008, p. 331; Oganov 2010, p. 212</ref> It is less dense than aluminium (2.34 vs. 2.70 g/cm³), and is hard and brittle. It is barely reactive under normal conditions, except for attack by fluorine,<ref>Housecroft & Sharpe 2008, p. 333</ref> and has a melting point of 2076 °C (cf. steel ~1370 °C).<ref>Kross 2011</ref> Boron is a semiconductor;<ref>Berger 1997, p. 37</ref> its room temperature electrical conductivity is 1.5 × 10⁻⁶ S•cm⁻¹<ref>Greenwood & Earnshaw 2002, p. 144</ref> (about 200 times less than that of tap water)<ref>Kopp, Lipták & Eren 2003, p. 221</ref> and it has a band gap of about 1.56 eV.<ref>Prudenziati 1977, p. 242</ref>Template:Refn Mendeleev commented that, "Boron appears in a free state in several forms which are intermediate between the metals and the nonmmetals."<ref>Mendeléeff 1897, p. 57</ref>

The structural chemistry of boron is dominated by its small atomic size, and relatively high ionization energy. With only three valence electrons per boron atom, simple covalent bonding cannot fulfil the octet rule.<ref name="Rayner-Canham 2006, p. 291">Rayner-Canham & Overton 2006, p. 291</ref> Metallic bonding is the usual result among the heavier congenors of boron but this generally requires low ionization energies.<ref>Siekierski & Burgess 2002, p. 63</ref> Instead, because of its small size and high ionization energies, the basic structural unit of boron (and nearly all of its allotropes)Template:Refn is the icosahedral B₁₂ cluster. Of the 36 electrons associated with 12 boron atoms, 26 reside in 13 delocalized molecular orbitals; the other 10 electrons are used to form two- and three-centre covalent bonds between icosahedra.<ref>Siekierski & Burgess 2002, p. 86</ref> The same motif can be seen, as are deltahedral variants or fragments, in metal borides and hydride derivatives, and in some halides.<ref>Greenwood & Earnshaw 2002, p. 141; Henderson 2000, p. 58; Housecroft & Sharpe 2008, pp. 360–72</ref>

The bonding in boron has been described as being characteristic of behaviour intermediate between metals and nonmetallic covalent network solids (such as diamond).<ref>Parry et al. 1970, pp. 438, 448–51</ref> The energy required to transform B, C, N, Si, and P from nonmetallic to metallic states has been estimated as 30, 100, 240, 33, and 50 kJ/mol, respectively. This indicates the proximity of boron to the metal-nonmetal borderline.<ref name=Fehlner1990>Fehlner 1990, p. 202</ref>

Most of the chemistry of boron is nonmetallic in nature.<ref name=Fehlner1990/> Unlike its heavier congeners, it is not known to form a simple B³⁺ or hydrated [B(H₂O)₄]³⁺ cation.<ref>Owen & Brooker 1991, p. 59; Wiberg 2001, p. 936</ref> The small size of the boron atom enables the preparation of many interstitial alloy-type borides.<ref name=Greenwood145>Greenwood & Earnshaw 2002, p. 145</ref> Analogies between boron and transition metals have been noted in the formation of complexes,<ref>Houghton 1979, p. 59</ref> and adducts (for example, BH₃ + CO →BH₃CO and, similarly, Fe(CO)₄ + CO →Fe(CO)₅),Template:Refn as well as in the geometric and electronic structures of cluster species such as [B₆H₆]²⁻ and [Ru₆(CO)₁₈]²⁻.<ref>Fehlner 1990, pp. 204–05, 207</ref>Template:Refn The aqueous chemistry of boron is characterised by the formation of many different polyborate anions.<ref>Salentine 1987, pp. 128–32; MacKay, MacKay & Henderson 2002, pp. 439–40; Kneen, Rogers & Simpson 1972, p. 394; Hiller & Herber 1960, inside front cover; p. 225</ref> Given its high charge-to-size ratio, boron bonds covalently in nearly all of its compounds;<ref>Sharp 1983, p. 56</ref> the exceptions are the borides as these include, depending on their composition, covalent, ionic, and metallic bonding components.<ref>Fokwa 2014, p. 10</ref>Template:Refn Simple binary compounds, such as boron trichloride are Lewis acids as the formation of three covalent bonds leaves a hole in the octet which can be filled by an electron-pair donated by a Lewis base.<ref name="Rayner-Canham 2006, p. 291"/> Boron has a strong affinity for oxygen and a duly extensive borate chemistry.<ref name=Greenwood145/> The oxide B₂O₃ is polymeric in structure,<ref name=Pudd59>Puddephatt & Monaghan 1989, p. 59</ref> weakly acidic,<ref>Mahan 1965, p. 485</ref>Template:Refn and a glass former.<ref name=Rao22>Rao 2002, p. 22</ref> Organometallic compounds of boronTemplate:Refn have been known since the 19th century (see organoboron chemistry).<ref>Haiduc & Zuckerman 1985, p. 82</ref>

SiliconEdit

{{#invoke:Labelled list hatnote|labelledList|Main article|Main articles|Main page|Main pages}}

Silicon is a crystalline solid with a blue-grey metallic lustre.<ref name=Greenwood331>Greenwood & Earnshaw 2002, p. 331</ref> Like boron, it is less dense (at 2.33 g/cm³) than aluminium, and is hard and brittle.<ref>Wiberg 2001, p. 824</ref> It is a relatively unreactive element.<ref name=Greenwood331/> According to Rochow,<ref>Rochow 1973, pp. 1337‒38</ref> the massive crystalline form (especially if pure) is "remarkably inert to all acids, including hydrofluoric".Template:Refn Less pure silicon, and the powdered form, are variously susceptible to attack by strong or heated acids, as well as by steam and fluorine.<ref>Rochow 1973, pp. 1337, 1340</ref> Silicon dissolves in hot aqueous alkalis with the evolution of hydrogen, as do metals<ref>Allen & Ordway 1968, p. 152</ref> such as beryllium, aluminium, zinc, gallium or indium.<ref>Eagleson 1994, pp. 48, 127, 438, 1194; Massey 2000, p. 191</ref> It melts at 1414 °C. Silicon is a semiconductor with an electrical conductivity of 10⁻⁴ S•cm⁻¹<ref>Orton 2004, p. 7. This is a typical value for high-purity silicon.</ref> and a band gap of about 1.11 eV.<ref name=R393>Russell & Lee 2005, p. 393</ref> When it melts, silicon becomes a reasonable metal<ref>Coles & Caplin 1976, p. 106</ref> with an electrical conductivity of 1.0–1.3 × 10⁴ S•cm⁻¹, similar to that of liquid mercury.<ref>Glazov, Chizhevskaya & Glagoleva 1969, pp. 59–63; Allen & Broughton 1987, p. 4967</ref>

The chemistry of silicon is generally nonmetallic (covalent) in nature.<ref>Cotton, Wilkinson & Gaus 1995, p. 393</ref> It is not known to form a cation.<ref>Wiberg 2001, p. 834</ref>Template:Refn Silicon can form alloys with metals such as iron and copper.<ref>Partington 1944, p. 723</ref> It shows fewer tendencies to anionic behaviour than ordinary nonmetals.<ref name=Cox>Cox 2004, p. 27</ref> Its solution chemistry is characterised by the formation of oxyanions.<ref name=Hiller225>Hiller & Herber 1960, inside front cover; p. 225</ref> The high strength of the silicon–oxygen bond dominates the chemical behaviour of silicon.<ref>Kneen, Rogers and Simpson 1972, p. 384</ref> Polymeric silicates, built up by tetrahedral SiO₄ units sharing their oxygen atoms, are the most abundant and important compounds of silicon.<ref name="Bailar513"/> The polymeric borates, comprising linked trigonal and tetrahedral BO₃ or BO₄ units, are built on similar structural principles.<ref>Cotton, Wilkinson & Gaus 1995, pp. 319, 321</ref> The oxide SiO₂ is polymeric in structure,<ref name=Pudd59/> weakly acidic,<ref>Smith 1990, p. 175</ref>Template:Refn and a glass former.<ref name=Rao22/> Traditional organometallic chemistry includes the carbon compounds of silicon (see organosilicon).<ref>Powell 1988, p. 1</ref>

GermaniumEdit

{{#invoke:Labelled list hatnote|labelledList|Main article|Main articles|Main page|Main pages}}

Germanium is a shiny grey-white solid.<ref>Greenwood & Earnshaw 2002, p. 371</ref> It has a density of 5.323 g/cm³ and is hard and brittle.<ref>Cusack 1967, p. 193</ref> It is mostly unreactive at room temperatureTemplate:Refn but is slowly attacked by hot concentrated sulfuric or nitric acid.<ref name=Greenwood373>Greenwood & Earnshaw 2002, p. 373</ref> Germanium also reacts with molten caustic soda to yield sodium germanate Na₂GeO₃ and hydrogen gas.<ref>Moody 1991, p. 273</ref> It melts at 938 °C. Germanium is a semiconductor with an electrical conductivity of around 2 × 10⁻² S•cm⁻¹<ref name=Greenwood373/> and a band gap of 0.67 eV.<ref>Russell & Lee 2005, p. 399</ref> Liquid germanium is a metallic conductor, with an electrical conductivity similar to that of liquid mercury.<ref>Berger 1997, pp. 71–72</ref>

Most of the chemistry of germanium is characteristic of a nonmetal.<ref>Jolly 1966, pp. 125–6</ref> Whether or not germanium forms a cation is unclear, aside from the reported existence of the Ge²⁺ ion in a few esoteric compounds.Template:Refn It can form alloys with metals such as aluminium and gold.<ref>Schwartz 2002, p. 269</ref> It shows fewer tendencies to anionic behaviour than ordinary nonmetals.<ref name=Cox/> Its solution chemistry is characterised by the formation of oxyanions.<ref name=Hiller225/> Germanium generally forms tetravalent (IV) compounds, and it can also form less stable divalent (II) compounds, in which it behaves more like a metal.<ref name="ReferenceC">Eggins 1972, p. 66; Wiberg 2001, p. 895</ref> Germanium analogues of all of the major types of silicates have been prepared.<ref>Greenwood & Earnshaw 2002, p. 383</ref> The metallic character of germanium is also suggested by the formation of various oxoacid salts. A phosphate [(HPO₄)₂Ge·H₂O] and highly stable trifluoroacetate Ge(OCOCF₃)₄ have been described, as have Ge₂(SO₄)₂, Ge(ClO₄)₄ and GeH₂(C₂O₄)₃.<ref>Glockling 1969, p. 38; Wells 1984, p. 1175</ref> The oxide GeO₂ is polymeric,<ref name=Pudd59/> amphoteric,<ref>Cooper 1968, pp. 28–29</ref> and a glass former.<ref name=Rao22/> The dioxide is soluble in acidic solutions (the monoxide GeO, is even more so), and this is sometimes used to classify germanium as a metal.<ref>Steele 1966, pp. 178, 188–89</ref> Up to the 1930s germanium was considered to be a poorly conducting metal;<ref>Haller 2006, p. 3</ref> it has occasionally been classified as a metal by later writers.<ref>See, for example, Walker & Tarn 1990, p. 590</ref> As with all the elements commonly recognised as metalloids, germanium has an established organometallic chemistry (see Organogermanium chemistry).<ref>Wiberg 2001, p. 742</ref>

ArsenicEdit

{{#invoke:Labelled list hatnote|labelledList|Main article|Main articles|Main page|Main pages}}

Arsenic is a grey, metallic looking solid. It has a density of 5.727 g/cm³ and is brittle, and moderately hard (more than aluminium; less than iron).<ref name="GWM2011">Gray, Whitby & Mann 2011</ref> It is stable in dry air but develops a golden bronze patina in moist air, which blackens on further exposure. Arsenic is attacked by nitric acid and concentrated sulfuric acid. It reacts with fused caustic soda to give the arsenate Na₃AsO₃ and hydrogen gas.<ref name="Greenwood 2002, p. 552">Greenwood & Earnshaw 2002, p. 552</ref> Arsenic sublimes at 615 °C. The vapour is lemon-yellow and smells like garlic.<ref>Parkes & Mellor 1943, p. 740</ref> Arsenic only melts under a pressure of 38.6 atm, at 817 °C.<ref>Russell & Lee 2005, p. 420</ref> It is a semimetal with an electrical conductivity of around 3.9 × 10⁴ S•cm⁻¹<ref name="Carapella1968p30">Carapella 1968, p. 30</ref> and a band overlap of 0.5 eV.<ref name="Barfuß 1981, p. 967">Barfuß et al. 1981, p. 967</ref>Template:Refn Liquid arsenic is a semiconductor with a band gap of 0.15 eV.<ref>Bailar & Trotman-Dickenson 1973, p. 558; Li 1990</ref>

The chemistry of arsenic is predominately nonmetallic.<ref>Bailar, Moeller & Kleinberg 1965, p. 477</ref> Whether or not arsenic forms a cation is unclear.Template:Refn Its many metal alloys are mostly brittle.<ref>Eagleson 1994, p. 91</ref> It shows fewer tendencies to anionic behaviour than ordinary nonmetals.<ref name=Cox/> Its solution chemistry is characterised by the formation of oxyanions.<ref name=Hiller225/> Arsenic generally forms compounds in which it has an oxidation state of +3 or +5.<ref name="Massey267">Massey 2000, p. 267</ref> The halides, and the oxides and their derivatives are illustrative examples.<ref name="Bailar513">Bailar, Moeller & Kleinberg 1965, p. 513</ref> In the trivalent state, arsenic shows some incipient metallic properties.<ref>Timm 1944, p. 454</ref> The halides are hydrolysed by water but these reactions, particularly those of the chloride, are reversible with the addition of a hydrohalic acid.<ref>Partington 1944, p. 641; Kleinberg, Argersinger & Griswold 1960, p. 419</ref> The oxide is acidic but, as noted below, (weakly) amphoteric. The higher, less stable, pentavalent state has strongly acidic (nonmetallic) properties.<ref>Morgan 1906, p. 163; Moeller 1954, p. 559</ref> Compared to phosphorus, the stronger metallic character of arsenic is indicated by the formation of oxoacid salts such as AsPO₄, As₂(SO₄)₃Template:Refn and arsenic acetate As(CH₃COO)₃.<ref>Zingaro 1994, p. 197; Emeléus & Sharpe 1959, p. 418; Addison & Sowerby 1972, p. 209; Mellor 1964, p. 337</ref> The oxide As₂O₃ is polymeric,<ref name=Pudd59/> amphoteric,<ref>Pourbaix 1974, p. 521; Eagleson 1994, p. 92; Greenwood & Earnshaw 2002, p. 572</ref>Template:Refn and a glass former.<ref name=Rao22/> Arsenic has an extensive organometallic chemistry (see Organoarsenic chemistry).<ref>Krannich & Watkins 2006</ref>

AntimonyEdit

{{#invoke:Labelled list hatnote|labelledList|Main article|Main articles|Main page|Main pages}}

Antimony is a silver-white solid with a blue tint and a brilliant lustre.<ref name="Greenwood 2002, p. 552"/> It has a density of 6.697 g/cm³ and is brittle, and moderately hard (more so than arsenic; less so than iron; about the same as copper).<ref name="GWM2011"/> It is stable in air and moisture at room temperature. It is attacked by concentrated nitric acid, yielding the hydrated pentoxide Sb₂O₅. Aqua regia gives the pentachloride SbCl₅ and hot concentrated sulfuric acid results in the sulfate Sb₂(SO₄)₃.<ref name="Greenwood 2002, p. 553">Greenwood & Earnshaw 2002, p. 553</ref> It is not affected by molten alkali.<ref>Dunstan 1968, p. 433</ref> Antimony is capable of displacing hydrogen from water, when heated: 2 Sb + 3 H₂O → Sb₂O₃ + 3 H₂.<ref>Parise 1996, p. 112</ref> It melts at 631 °C. Antimony is a semimetal with an electrical conductivity of around 3.1 × 10⁴ S•cm⁻¹<ref>Carapella 1968a, p. 23</ref> and a band overlap of 0.16 eV.<ref name="Barfuß 1981, p. 967"/>Template:Refn Liquid antimony is a metallic conductor with an electrical conductivity of around 5.3 × 10⁴ S•cm⁻¹.<ref>Dupree, Kirby & Freyland 1982, p. 604; Mhiaoui, Sar, & Gasser 2003</ref>

Most of the chemistry of antimony is characteristic of a nonmetal.<ref>Kotz, Treichel & Weaver 2009, p. 62</ref> Antimony has some definite cationic chemistry,<ref>Cotton et al. 1999, p. 396</ref> SbO⁺ and Sb(OH)₂⁺ being present in acidic aqueous solution;<ref>King 1994, p. 174</ref>Template:Refn the compound Sb₈(GaCl₄)₂, which contains the homopolycation, Sb₈²⁺, was prepared in 2004.<ref>Lindsjö, Fischer & Kloo 2004</ref> It can form alloys with one or more metals such as aluminium,<ref>Friend 1953, p. 87</ref> iron, nickel, copper, zinc, tin, lead, and bismuth.<ref>Fesquet 1872, pp. 109–14</ref> Antimony has fewer tendencies to anionic behaviour than ordinary nonmetals.<ref name=Cox/> Its solution chemistry is characterised by the formation of oxyanions.<ref name=Hiller225/> Like arsenic, antimony generally forms compounds in which it has an oxidation state of +3 or +5.<ref name=Massey267/> The halides, and the oxides and their derivatives are illustrative examples.<ref name=Bailar513/> The +5 state is less stable than the +3, but relatively easier to attain than with arsenic. This is explained by the poor shielding afforded the arsenic nucleus by its 3d¹⁰ electrons. In comparison, the tendency of antimony (being a heavier atom) to oxidize more easily partially offsets the effect of its 4d¹⁰ shell.<ref>Greenwood & Earnshaw 2002, p. 553; Massey 2000, p. 269</ref> Tripositive antimony is amphoteric; pentapositive antimony is (predominately) acidic.<ref>King 1994, p. 171</ref> Consistent with an increase in metallic character down group 15, antimony forms salts including an acetate Sb(CH₃CO₂)₃, phosphate SbPO₄, sulfate Sb₂(SO₄)₃ and perchlorate Sb(ClO₄)₃.<ref>Turova 2011, p. 46</ref> The otherwise acidic pentoxide Sb₂O₅ shows some basic (metallic) behaviour in that it can be dissolved in very acidic solutions, with the formation of the oxycation SbOTemplate:Su.<ref>Pourbaix 1974, p. 530</ref> The oxide Sb₂O₃ is polymeric,<ref name=Pudd59/> amphoteric,<ref name="Wiberg2001p764">Wiberg 2001, p. 764</ref> and a glass former.<ref name=Rao22/> Antimony has an extensive organometallic chemistry (see Organoantimony chemistry).<ref>House 2008, p. 497</ref>

TelluriumEdit

{{#invoke:Labelled list hatnote|labelledList|Main article|Main articles|Main page|Main pages}}

Tellurium is a silvery-white shiny solid.<ref>Emsley 2001, p. 428</ref> It has a density of 6.24 g/cm³, is brittle, and is the softest of the commonly recognised metalloids, being marginally harder than sulfur.<ref name="GWM2011"/> Large pieces of tellurium are stable in air. The finely powdered form is oxidized by air in the presence of moisture. Tellurium reacts with boiling water, or when freshly precipitated even at 50 °C, to give the dioxide and hydrogen: Te + 2 H₂O → TeO₂ + 2 H₂.<ref name=Kudryavtsev78>Kudryavtsev 1974, p. 78</ref> It reacts (to varying degrees) with nitric, sulfuric, and hydrochloric acids to give compounds such as the sulfoxide TeSO₃ or tellurous acid H₂TeO₃,<ref>Bagnall 1966, pp. 32–33, 59, 137</ref> the basic nitrate (Te₂O₄H)⁺(NO₃)⁻,<ref>Swink et al. 1966; Anderson et al. 1980</ref> or the oxide sulfate Te₂O₃(SO₄).<ref>Ahmed, Fjellvåg & Kjekshus 2000</ref> It dissolves in boiling alkalis, to give the tellurite and telluride: 3 Te + 6 KOH = K₂TeO₃ + 2 K₂Te + 3 H₂O, a reaction that proceeds or is reversible with increasing or decreasing temperature.<ref>Chizhikov & Shchastlivyi 1970, p. 28</ref>

At higher temperatures tellurium is sufficiently plastic to extrude.<ref>Kudryavtsev 1974, p. 77</ref> It melts at 449.51 °C. Crystalline tellurium has a structure consisting of parallel infinite spiral chains. The bonding between adjacent atoms in a chain is covalent, but there is evidence of a weak metallic interaction between the neighbouring atoms of different chains.<ref name="Stuke1074p178">Stuke 1974, p. 178; Donohue 1982, pp. 386–87; Cotton et al. 1999, p. 501</ref> Tellurium is a semiconductor with an electrical conductivity of around 1.0 S•cm⁻¹<ref>Becker, Johnson & Nussbaum 1971, p. 56</ref> and a band gap of 0.32 to 0.38 eV.<ref name=Berger90>Berger 1997, p. 90</ref> Liquid tellurium is a semiconductor, with an electrical conductivity, on melting, of around 1.9 × 10³ S•cm⁻¹.<ref name=Berger90/> Superheated liquid tellurium is a metallic conductor.<ref>Chizhikov & Shchastlivyi 1970, p. 16</ref>

Most of the chemistry of tellurium is characteristic of a nonmetal.<ref>Jolly 1966, pp. 66–67</ref> It shows some cationic behaviour. The dioxide dissolves in acid to yield the trihydroxotellurium(IV) Te(OH)₃⁺ ion;<ref>Schwietzer & Pesterfield 2010, p. 239</ref>Template:Refn the red Te₄²⁺ and yellow-orange Te₆²⁺ ions form when tellurium is oxidized in fluorosulfuric acid (HSO₃F), or liquid sulfur dioxide (SO₂), respectively.<ref>Wiberg 2001, p. 588</ref> It can form alloys with aluminium, silver, and tin.<ref>Mellor 1964a, p.  30; Wiberg 2001, p. 589</ref> Tellurium shows fewer tendencies to anionic behaviour than ordinary nonmetals.<ref name=Cox/> Its solution chemistry is characterised by the formation of oxyanions.<ref name=Hiller225/> Tellurium generally forms compounds in which it has an oxidation state of −2, +4 or +6. The +4 state is the most stable.<ref name=Kudryavtsev78/> Tellurides of composition X_xTe_y are easily formed with most other elements and represent the most common tellurium minerals. Nonstoichiometry is pervasive, especially with transition metals. Many tellurides can be regarded as metallic alloys.<ref>Greenwood & Earnshaw 2002, pp. 765–66</ref> The increase in metallic character evident in tellurium, as compared to the lighter chalcogens, is further reflected in the reported formation of various other oxyacid salts, such as a basic selenate 2TeO₂·SeO₃ and an analogous perchlorate and periodate 2TeO₂·HXO₄.<ref>Bagnall 1966, pp. 134–51; Greenwood & Earnshaw 2002, p. 786</ref> Tellurium forms a polymeric,<ref name=Pudd59/> amphoteric,<ref name="Wiberg2001p764"/> glass-forming oxide<ref name=Rao22/> TeO₂. It is a "conditional" glass-forming oxide – it forms a glass with a very small amount of additive.<ref name=Rao22/> Tellurium has an extensive organometallic chemistry (see Organotellurium chemistry).<ref>Detty & O'Regan 1994, pp. 1–2</ref>

Elements less commonly recognised as metalloidsEdit

CarbonEdit

{{#invoke:Labelled list hatnote|labelledList|Main article|Main articles|Main page|Main pages}}

Carbon is ordinarily classified as a nonmetal<ref>Chang 2002, p. 314</ref> but has some metallic properties and is occasionally classified as a metalloid.<ref>Kent 1950, pp. 1–2; Clark 1960, p. 588; Warren & Geballe 1981</ref> Hexagonal graphitic carbon (graphite) is the most thermodynamically stable allotrope of carbon under ambient conditions.<ref>Housecroft & Sharpe 2008, p. 384; IUPAC 2006–, rhombohedral graphite entry</ref> It has a lustrous appearance<ref>Mingos 1998, p. 171</ref> and is a fairly good electrical conductor.<ref>Wiberg 2001, p. 781</ref> Graphite has a layered structure. Each layer consists of carbon atoms bonded to three other carbon atoms in a hexagonal lattice arrangement. The layers are stacked together and held loosely by van der Waals forces and delocalized valence electrons.<ref>Charlier, Gonze & Michenaud 1994</ref>

The electrical conductivity of graphite is high parallel to its planes (30 kS/cm at 25°C), and decreases with increasing temperature, indicating semimetallic behaviour along that direction. Perpendicular to the planes, graphite behaves as a semiconductor: the conductivity is low (5 S/cm) but increases as the temperature rises.<ref name="Atkins320">Atkins et al. 2006, pp. 320–21</ref>Template:Refn The allotropes of carbon, including graphite, can accept foreign atoms or compounds into their structures via substitution, intercalation, or doping. The resulting materials are sometimes referred to as "carbon alloys".<ref>Inagaki 2000, p. 216; Yasuda et al. 2003, pp. 3–11</ref> Carbon can form ionic salts, including a hydrogen sulfate, perchlorate, and nitrate (CTemplate:SuX⁻.2HX, where X = HSO₄, ClO₄; and CTemplate:SuNOTemplate:Su.3HNO₃).<ref>O'Hare 1997, p. 230</ref>Template:Refn In organic chemistry, carbon can form complex cationsTemplate:Sndtermed carbocationsTemplate:Sndin which the positive charge is on the carbon atom; examples are [[carbenium ion|Template:Chem]] and [[carbonium ion|Template:Chem]], and their derivatives.<ref>Traynham 1989, pp. 930–31; Prakash & Schleyer 1997</ref>

Graphite is an established solid lubricant and behaves as a semiconductor in a direction perpendicular to its planes.<ref name=Atkins320/> Most of its chemistry is nonmetallic;<ref>Bailar et al. 1989, p. 743</ref> it has a relatively high ionization energy<ref>Moore et al. 1985</ref> and, compared to most metals, a relatively high electronegativity.<ref>House & House 2010, p. 526</ref> Carbon can form anions such as C⁴⁻ (methanide), CTemplate:Su (acetylide), and CTemplate:Su (sesquicarbide or allylenide), in compounds with metals of main groups 1–3, and with the lanthanides and actinides.<ref>Wiberg 2001, p. 798</ref> Its oxide CO₂ forms carbonic acid H₂CO₃.<ref>Eagleson 1994, p. 175</ref>Template:Refn

AluminiumEdit

{{#invoke:Labelled list hatnote|labelledList|Main article|Main articles|Main page|Main pages}}

Aluminium is ordinarily classified as a metal.<ref>Keevil 1989, p. 103</ref> It is lustrous, malleable and ductile, and has high electrical and thermal conductivity. Like most metals it has a close-packed crystalline structure,<ref>Russell & Lee 2005, pp. 358–60 et seq</ref> and forms a cation in aqueous solution.<ref>Harding, Janes & Johnson 2002, p. 118</ref>

It has some properties that are unusual for a metal; taken together,<ref name="Metcalfe et al. 1974, p.539">Metcalfe, Williams & Castka 1974, p. 539</ref> these are sometimes used as a basis to classify aluminium as a metalloid.<ref>Cobb & Fetterolf 2005, p. 64; Metcalfe, Williams & Castka 1974, p. 539</ref> Its crystalline structure shows some evidence of directional bonding.<ref>Ogata, Li & Yip 2002; Boyer et al. 2004, p. 1023; Russell & Lee 2005, p. 359</ref> Aluminium bonds covalently in most compounds.<ref>Cooper 1968, p. 25; Henderson 2000, p. 5; Silberberg 2006, p. 314</ref> The oxide Al₂O₃ is amphoteric<ref>Wiberg 2001, p. 1014</ref> and a conditional glass-former.<ref name=Rao22/> Aluminium can form anionic aluminates,<ref name="Metcalfe et al. 1974, p.539"/> such behaviour being considered nonmetallic in character.<ref name="Hamm 1969, p.653">Hamm 1969, p. 653</ref>

Classifying aluminium as a metalloid has been disputed<ref>Daub & Seese 1996, pp. 70, 109: "Aluminum is not a metalloid but a metal because it has mostly metallic properties."; Denniston, Topping & Caret 2004, p. 57: "Note that aluminum (Al) is classified as a metal, not a metalloid."; Hasan 2009, p. 16: "Aluminum does not have the characteristics of a metalloid but rather those of a metal."</ref> given its many metallic properties. It is therefore, arguably, an exception to the mnemonic that elements adjacent to the metal–nonmetal dividing line are metalloids.<ref>Holt, Rinehart & Wilson c. 2007</ref>Template:Refn

Stott<ref>Stott 1956, p. 100</ref> labels aluminium as a weak metal. It has the physical properties of a metal but some of the chemical properties of a nonmetal. Steele<ref>Steele 1966, p. 60</ref> notes the paradoxical chemical behaviour of aluminium: "It resembles a weak metal in its amphoteric oxide and in the covalent character of many of its compounds ... Yet it is a highly electropositive metal ... [with] a high negative electrode potential". Moody<ref>Moody 1991, p. 303</ref> says that, "aluminium is on the 'diagonal borderland' between metals and non-metals in the chemical sense."

SeleniumEdit

{{#invoke:Labelled list hatnote|labelledList|Main article|Main articles|Main page|Main pages}}

Selenium shows borderline metalloid or nonmetal behaviour.<ref>Young et al. 2010, p. 9; Craig & Maher 2003, p. 391. Selenium is "near metalloidal".</ref>Template:Refn

Its most stable form, the grey trigonal allotrope, is sometimes called "metallic" selenium because its electrical conductivity is several orders of magnitude greater than that of the red monoclinic form.<ref>Moss 1952, p. 192</ref> The metallic character of selenium is further shown by its lustre,<ref name="Glinka 1965, p.356">Glinka 1965, p. 356</ref> and its crystalline structure, which is thought to include weakly "metallic" interchain bonding.<ref>Evans 1966, pp. 124–25</ref> Selenium can be drawn into thin threads when molten and viscous.<ref>Regnault 1853, p. 208</ref> It shows reluctance to acquire "the high positive oxidation numbers characteristic of nonmetals".<ref>Scott & Kanda 1962, p. 311</ref> It can form cyclic polycations (such as SeTemplate:Su) when dissolved in oleums<ref>Cotton et al. 1999, pp. 496, 503–04</ref> (an attribute it shares with sulfur and tellurium), and a hydrolysed cationic salt in the form of trihydroxoselenium(IV) perchlorate [Se(OH)₃]⁺·ClOTemplate:Su.<ref>Arlman 1939; Bagnall 1966, pp. 135, 142–43</ref>

The nonmetallic character of selenium is shown by its brittleness<ref name="Glinka 1965, p.356"/> and the low electrical conductivity (~10⁻⁹ to 10⁻¹² S•cm⁻¹) of its highly purified form.<ref name="Kozyrev">Kozyrev 1959, p. 104; Chizhikov & Shchastlivyi 1968, p. 25; Glazov, Chizhevskaya & Glagoleva 1969, p. 86</ref> This is comparable to or less than that of bromine (7.95Template:E S•cm⁻¹),<ref>Chao & Stenger 1964</ref> a nonmetal. Selenium has the electronic band structure of a semiconductor<ref name="Berger 1997, pp.86–7">Berger 1997, pp. 86–87</ref> and retains its semiconducting properties in liquid form.<ref name="Berger 1997, pp.86–7"/> It has a relatively high<ref>Snyder 1966, p. 242</ref> electronegativity (2.55 revised Pauling scale). Its reaction chemistry is mainly that of its nonmetallic anionic forms Se²⁻, SeOTemplate:Su and SeOTemplate:Su.<ref>Fritz & Gjerde 2008, p. 235</ref>

Selenium is commonly described as a metalloid in the environmental chemistry literature.<ref>Meyer et al. 2005, p. 284; Manahan 2001, p. 911; Szpunar et al. 2004, p. 17</ref> It moves through the aquatic environment similarly to arsenic and antimony;<ref>US Environmental Protection Agency 1988, p. 1; Uden 2005, pp. 347‒48</ref> its water-soluble salts, in higher concentrations, have a similar toxicological profile to that of arsenic.<ref>De Zuane 1997, p. 93; Dev 2008, pp. 2‒3</ref>

PoloniumEdit

{{#invoke:Labelled list hatnote|labelledList|Main article|Main articles|Main page|Main pages}} Polonium is "distinctly metallic" in some ways.<ref name="Cotton FA 1999, p.502">Cotton et al. 1999, p. 502</ref> Both of its allotropic forms are metallic conductors.<ref name="Cotton FA 1999, p.502"/> It is soluble in acids, forming the rose-coloured Po²⁺ cation and displacing hydrogen: Po + 2 H⁺ → Po²⁺ + H₂.<ref>Wiberg 2001, p. 594</ref> Many polonium salts are known.<ref>Greenwood & Earnshaw 2002, p. 786; Schwietzer & Pesterfield 2010, pp. 242–43</ref> The oxide PoO₂ is predominantly basic in nature.<ref name=Bagnall1966p41>Bagnall 1966, p. 41; Nickless 1968, p. 79</ref> Polonium is a reluctant oxidizing agent, unlike its lightest congener oxygen: highly reducing conditions are required for the formation of the Po²⁻ anion in aqueous solution.<ref>Bagnall 1990, pp. 313–14; Lehto & Hou 2011, p. 220; Siekierski & Burgess 2002, p. 117: "The tendency to form X²⁻ anions decreases down the Group [16 elements] ..."</ref>

Whether polonium is ductile or brittle is unclear. It is predicted to be ductile based on its calculated elastic constants.<ref>Legit, Friák & Šob 2010, pp. 214118–18</ref> It has a simple cubic crystalline structure. Such a structure has few slip systems and "leads to very low ductility and hence low fracture resistance".<ref>Manson & Halford 2006, pp. 378, 410</ref>

Polonium shows nonmetallic character in its halides, and by the existence of polonides. The halides have properties generally characteristic of nonmetal halides (being volatile, easily hydrolyzed, and soluble in organic solvents).<ref>Bagnall 1957, p. 62; Fernelius 1982, p. 741</ref> Many metal polonides, obtained by heating the elements together at 500–1,000 °C, and containing the Po²⁻ anion, are also known.<ref>Bagnall 1966, p. 41; Barrett 2003, p. 119</ref>

AstatineEdit

{{#invoke:Labelled list hatnote|labelledList|Main article|Main articles|Main page|Main pages}} As a halogen, astatine tends to be classified as a nonmetal.<ref>Hawkes 2010; Holt, Rinehart & Wilson c. 2007; Hawkes 1999, p. 14; Roza 2009, p. 12</ref> It has some marked metallic properties<ref>Keller 1985</ref> and is sometimes instead classified as either a metalloid<ref>Harding, Johnson & Janes 2002, p. 61</ref> or (less often) as a metal.Template:Refn Immediately following its production in 1940, early investigators considered it a metal.<ref>Vasáros & Berei 1985, p. 109</ref> In 1949 it was called the most noble (difficult to reduce) nonmetal as well as being a relatively noble (difficult to oxidize) metal.<ref>Haissinsky & Coche 1949, p. 400</ref> In 1950 astatine was described as a halogen and (therefore) a reactive nonmetal.<ref>Brownlee et al. 1950, p. 173</ref> In 2013, on the basis of relativistic modelling, astatine was predicted to be a monatomic metal, with a face-centred cubic crystalline structure.<ref>Hermann, Hoffmann & Ashcroft 2013</ref>

Several authors have commented on the metallic nature of some of the properties of astatine. Since iodine is a semiconductor in the direction of its planes, and since the halogens become more metallic with increasing atomic number, it has been presumed that astatine would be a metal if it could form a condensed phase.<ref>Siekierski & Burgess 2002, pp. 65, 122</ref>Template:Refn Astatine may be metallic in the liquid state on the basis that elements with an enthalpy of vaporization (∆H_vap) greater than ~42 kJ/mol are metallic when liquid.<ref name="Rao & Ganguly 1986">Rao & Ganguly 1986</ref> Such elements include boron,Template:Refn silicon, germanium, antimony, selenium, and tellurium. Estimated values for ∆H_vap of diatomic astatine are 50 kJ/mol or higher;<ref>Vasáros & Berei 1985, p. 117</ref> diatomic iodine, with a ∆H_vap of 41.71,<ref>Kaye & Laby 1973, p. 228</ref> falls just short of the threshold figure.

"Like typical metals, it [astatine] is precipitated by hydrogen sulfide even from strongly acid solutions and is displaced in a free form from sulfate solutions; it is deposited on the cathode on electrolysis."<ref>Samsonov 1968, p. 590</ref>Template:Refn Further indications of a tendency for astatine to behave like a (heavy) metal are: "... the formation of pseudohalide compounds ... complexes of astatine cations ... complex anions of trivalent astatine ... as well as complexes with a variety of organic solvents".<ref>Rossler 1985, pp. 143–44</ref> It has also been argued that astatine demonstrates cationic behaviour, by way of stable At⁺ and AtO⁺ forms, in strongly acidic aqueous solutions.<ref>Champion et al. 2010</ref>

Some of astatine's reported properties are nonmetallic. It has been extrapolated to have the narrow liquid range ordinarily associated with nonmetals (mp 302 °C; bp 337 °C),<ref>Borst 1982, pp. 465, 473</ref> although experimental indications suggest a lower boiling point of about 230±3 °C. Batsanov gives a calculated band gap energy for astatine of 0.7 eV;<ref>Batsanov 1971, p. 811</ref> this is consistent with nonmetals (in physics) having separated valence and conduction bands and thereby being either semiconductors or insulators.<ref>Swalin 1962, p. 216; Feng & Lin 2005, p. 157</ref> The chemistry of astatine in aqueous solution is mainly characterised by the formation of various anionic species.<ref>Schwietzer & Pesterfield 2010, pp. 258–60</ref> Most of its known compounds resemble those of iodine,<ref>Hawkes 1999, p. 14</ref> which is a halogen and a nonmetal.<ref>Olmsted & Williams 1997, p. 328; Daintith 2004, p. 277</ref> Such compounds include astatides (XAt), astatates (XAtO₃), and monovalent interhalogen compounds.<ref>Eberle1985, pp. 213–16, 222–27</ref>

Restrepo et al.<ref>Restrepo et al. 2004, p. 69; Restrepo et al. 2006, p. 411</ref> reported that astatine appeared to be more polonium-like than halogen-like. They did so on the basis of detailed comparative studies of the known and interpolated properties of 72 elements.

Related conceptsEdit

Near metalloidsEdit

In the periodic table, some of the elements adjacent to the commonly recognised metalloids, although usually classified as either metals or nonmetals, are occasionally referred to as near-metalloids<ref>Craig & Maher 2003, p. 391; Schroers 2013, p. 32; Vernon 2013, pp. 1704–05</ref> or noted for their metalloidal character. To the left of the metal–nonmetal dividing line, such elements include gallium,<ref>Cotton et al. 1999, p. 42</ref> tin<ref>Marezio & Licci 2000, p. 11</ref> and bismuth.<ref name=Vernon/> They show unusual packing structures,<ref>Russell & Lee 2005, p. 5</ref> marked covalent chemistry (molecular or polymeric),<ref>Parish 1977, pp. 178, 192–93</ref> and amphoterism.<ref>Eggins 1972, p. 66; Rayner-Canham & Overton 2006, pp. 29–30</ref> To the right of the dividing line are carbon,<ref>Atkins et al. 2006, pp. 320–21; Bailar et al. 1989, pp. 742–43</ref> phosphorus,<ref>Rochow 1966, p. 7; Taniguchi et al. 1984, p. 867: "... black phosphorus ... [is] characterized by the wide valence bands with rather delocalized nature."; Morita 1986, p. 230; Carmalt & Norman 1998, p. 7: "Phosphorus ... should therefore be expected to have some metalloid properties."; Du et al. 2010. Interlayer interactions in black phosphorus, which are attributed to van der Waals-Keesom forces, are thought to contribute to the smaller band gap of the bulk material (calculated 0.19 eV; observed 0.3 eV) as opposed to the larger band gap of a single layer (calculated ~0.75 eV).</ref> selenium<ref>Stuke 1974, p. 178; Cotton et al. 1999, p. 501; Craig & Maher 2003, p. 391</ref> and iodine.<ref>Steudel 1977, p. 240: "... considerable orbital overlap must exist, to form intermolecular, many-center ... [sigma] bonds, spread through the layer and populated with delocalized electrons, reflected in the properties of iodine (lustre, color, moderate electrical conductivity)."; Segal 1989, p. 481: "Iodine exhibits some metallic properties ..."</ref> They exhibit metallic lustre, semiconducting propertiesTemplate:Refn and bonding or valence bands with delocalized character. This applies to their most thermodynamically stable forms under ambient conditions: carbon as graphite; phosphorus as black phosphorus;Template:Refn and selenium as grey selenium.

AllotropesEdit

Different crystalline forms of an element are called allotropes. Some allotropes, particularly those of elements located (in periodic table terms) alongside or near the notional dividing line between metals and nonmetals, exhibit more pronounced metallic, metalloidal or nonmetallic behaviour than others.<ref>Brescia et al. 1980, pp. 166–71</ref> The existence of such allotropes can complicate the classification of the elements involved.<ref>Fine & Beall 1990, p. 578</ref>

Tin, for example, has two allotropes: tetragonal "white" β-tin and cubic "grey" α-tin. White tin is a very shiny, ductile and malleable metal. It is the stable form at or above room temperature and has an electrical conductivity of 9.17 × 10⁴ S·cm⁻¹ (~1/6th that of copper).<ref>Wiberg 2001, p. 901</ref> Grey tin usually has the appearance of a grey micro-crystalline powder, and can also be prepared in brittle semi-lustrous crystalline or polycrystalline forms. It is the stable form below 13.2 °C and has an electrical conductivity of between (2–5) × 10² S·cm⁻¹ (~1/250th that of white tin).<ref>Berger 1997, p. 80</ref> Grey tin has the same crystalline structure as that of diamond. It behaves as a semiconductor (as if it had a band gap of 0.08 eV), but has the electronic band structure of a semimetal.<ref>Lovett 1977, p. 101</ref> It has been referred to as either a very poor metal,<ref>Cohen & Chelikowsky 1988, p. 99</ref> a metalloid,<ref>Taguena-Martinez, Barrio & Chambouleyron 1991, p. 141</ref> a nonmetal<ref>Ebbing & Gammon 2010, p. 891</ref> or a near metalloid.<ref name=Vernon>Vernon 2013, p. 1705</ref>

The diamond allotrope of carbon is clearly nonmetallic, being translucent and having a low electrical conductivity of 10⁻¹⁴ to 10⁻¹⁶ S·cm⁻¹.<ref>Asmussen & Reinhard 2002, p. 7</ref> Graphite has an electrical conductivity of 3 × 10⁴ S·cm⁻¹,<ref>Deprez & McLachan 1988</ref> a figure more characteristic of a metal. Phosphorus, sulfur, arsenic, selenium, antimony, and bismuth also have less stable allotropes that display different behaviours.<ref>Addison 1964 (P, Se, Sn); Marković, Christiansen & Goldman 1998 (Bi); Nagao et al. 2004</ref>

Abundance, extraction, and costEdit

AbundanceEdit

The table gives crustal abundances of the elements commonly to rarely recognised as metalloids.<ref>Lide 2005; Wiberg 2001, p. 423: At</ref> Some other elements are included for comparison: oxygen and xenon (the most and least abundant elements with stable isotopes); iron and the coinage metals copper, silver, and gold; and rhenium, the least abundant stable metal (aluminium is normally the most abundant metal). Various abundance estimates have been published; these often disagree to some extent.<ref>Cox 1997, pp. 182‒86</ref>

ExtractionEdit

The recognised metalloids can be obtained by chemical reduction of either their oxides or their sulfides. Simpler or more complex extraction methods may be employed depending on the starting form and economic factors.<ref>MacKay, MacKay & Henderson 2002, p. 204</ref> Boron is routinely obtained by reducing the trioxide with magnesium: B₂O₃ + 3 Mg → 2 B + 3MgO; after secondary processing the resulting brown powder has a purity of up to 97%.<ref>Baudis 2012, pp. 207–08</ref> Boron of higher purity (> 99%) is prepared by heating volatile boron compounds, such as BCl₃ or BBr₃, either in a hydrogen atmosphere (2 BX₃ + 3 H₂ → 2 B + 6 HX) or to the point of thermal decomposition. Silicon and germanium are obtained from their oxides by heating the oxide with carbon or hydrogen: SiO₂ + C → Si + CO₂; GeO₂ + 2 H₂ → Ge + 2 H₂O. Arsenic is isolated from its pyrite (FeAsS) or arsenical pyrite (FeAs₂) by heating; alternatively, it can be obtained from its oxide by reduction with carbon: 2 As₂O₃ + 3 C → 2 As + 3 CO₂.<ref>Wiberg 2001, p. 741</ref> Antimony is derived from its sulfide by reduction with iron: Sb₂S₃ → 2 Sb + 3 FeS. Tellurium is prepared from its oxide by dissolving it in aqueous NaOH, yielding tellurite, then by electrolytic reduction: TeO₂ + 2 NaOH → Na₂TeO₃ + H₂O;<ref>Chizhikov & Shchastlivyi 1968, p. 96</ref> Na₂TeO₃ + H₂O → Te + 2 NaOH + O₂.<ref>Greenwood & Earnshaw 2002, pp. 140–41, 330, 369, 548–59, 749: B, Si, Ge, As, Sb, Te</ref> Another option is reduction of the oxide by roasting with carbon: TeO₂ + C → Te + CO₂.<ref>Kudryavtsev 1974, p. 158</ref>

Production methods for the elements less frequently recognised as metalloids involve natural processing, electrolytic or chemical reduction, or irradiation. Carbon (as graphite) occurs naturally and is extracted by crushing the parent rock and floating the lighter graphite to the surface. Aluminium is extracted by dissolving its oxide Al₂O₃ in molten cryolite Na₃AlF₆ and then by high temperature electrolytic reduction. Selenium is produced by roasting the coinage metal selenides X₂Se (X = Cu, Ag, Au) with soda ash to give the selenite: X₂Se + O₂ + Na₂CO₃ → Na₂SeO₃ + 2 X + CO₂; the selenide is neutralized by sulfuric acid H₂SO₄ to give selenous acid H₂SeO₃; this is reduced by bubbling with SO₂ to yield elemental selenium. Polonium and astatine are produced in minute quantities by irradiating bismuth.<ref>Greenwood & Earnshaw 2002, pp. 271, 219, 748–49, 886: C, Al, Se, Po, At; Wiberg 2001, p. 573: Se</ref>

CostEdit

The recognised metalloids and their closer neighbours mostly cost less than silver; only polonium and astatine are more expensive than gold, on account of their significant radioactivity. As of 5 April 2014, prices for small samples (up to 100 g) of silicon, antimony and tellurium, and graphite, aluminium and selenium, average around one third the cost of silver (US$1.5 per gram or about $45 an ounce). Boron, germanium, and arsenic samples average about three-and-a-half times the cost of silver.Template:Refn Polonium is available for about $100 per microgram.<ref>United Nuclear 2013</ref> Zalutsky and Pruszynski<ref>Zalutsky & Pruszynski 2011, p. 181</ref> estimate a similar cost for producing astatine. Prices for the applicable elements traded as commodities tend to range from two to three times cheaper than the sample price (Ge), to nearly three thousand times cheaper (As).Template:Refn

NotesEdit

Template:Reflist

ReferencesEdit

Template:Reflist

SourcesEdit

Template:Div col

• Addison WE 1964, The Allotropy of the Elements, Oldbourne Press, London
• Addison CC & Sowerby DB 1972, Main Group Elements: Groups V and VI, Butterworths, London, Template:ISBN
• Adler D 1969, 'Half-way Elements: The Technology of Metalloids', book review, Technology Review, vol. 72, no. 1, Oct/Nov, pp. 18–19, {{#if:0040-1692|Template:Catalog lookup link{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}}}}}}}}}}}}}}}}}}}|Template:Error-small}}
• Ahmed MAK, Fjellvåg H & Kjekshus A 2000, 'Synthesis, Structure and Thermal Stability of Tellurium Oxides and Oxide Sulfate Formed from Reactions in Refluxing Sulfuric Acid', Journal of the Chemical Society, Dalton Transactions, no. 24, pp. 4542–49, {{#invoke:doi|main}}
• Ahmeda E & Rucka M 2011, 'Homo- and heteroatomic polycations of groups 15 and 16. Recent advances in synthesis and isolation using room temperature ionic liquids', Coordination Chemistry Reviews, vol. 255, nos 23–24, pp. 2892–903, {{#invoke:doi|main}}
• Allen DS & Ordway RJ 1968, Physical Science, 2nd ed., Van Nostrand, Princeton, New Jersey, Template:ISBN
• Allen PB & Broughton JQ 1987, 'Electrical Conductivity and Electronic Properties of Liquid Silicon', Journal of Physical Chemistry, vol. 91, no. 19, pp. 4964–70, {{#invoke:doi|main}}
• Alloul H 2010, Introduction to the Physics of Electrons in Solids, Springer-Verlag, Berlin, Template:ISBN
• Anderson JB, Rapposch MH, Anderson CP & Kostiner E 1980, 'Crystal Structure Refinement of Basic Tellurium Nitrate: A Reformulation as (Te₂O₄H)⁺(NO₃)⁻', Monatshefte für Chemie/ Chemical Monthly, vol. 111, no. 4, pp. 789–96, {{#invoke:doi|main}}
• Antman KH 2001, 'Introduction: The History of Arsenic Trioxide in Cancer Therapy', The Oncologist, vol. 6, suppl. 2, pp. 1–2, {{#invoke:doi|main}}
• Apseloff G 1999, 'Therapeutic Uses of Gallium Nitrate: Past, Present, and Future', American Journal of Therapeutics, vol. 6, no. 6, pp. 327–39, {{#if:1536-3686|Template:Catalog lookup link{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}}}}}}}}}}}}}}}}}}}|Template:Error-small}}
• Arlman EJ 1939, 'The Complex Compounds P(OH)₄.ClO₄ and Se(OH)₃.ClO₄', Recueil des Travaux Chimiques des Pays-Bas, vol. 58, no. 10, pp. 871–74, {{#if:0165-0513|Template:Catalog lookup link{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}}}}}}}}}}}}}}}}}}}|Template:Error-small}}
• Askeland DR, Phulé PP & Wright JW 2011, The Science and Engineering of Materials, 6th ed., Cengage Learning, Stamford, CT, Template:ISBN
• Asmussen J & Reinhard DK 2002, Diamond Films Handbook, Marcel Dekker, New York, Template:ISBN
• Atkins P, Overton T, Rourke J, Weller M & Armstrong F 2006, Shriver & Atkins' Inorganic Chemistry, 4th ed., Oxford University Press, Oxford, Template:ISBN
• Atkins P, Overton T, Rourke J, Weller M & Armstrong F 2010, Shriver & Atkins' Inorganic Chemistry, 5th ed., Oxford University Press, Oxford, Template:ISBN
• Austen K 2012, 'A Factory for Elements that Barely Exist', New Scientist, 21 Apr, p. 12
• Ba LA, Döring M, Jamier V & Jacob C 2010, 'Tellurium: an Element with Great Biological Potency and Potential', Organic & Biomolecular Chemistry, vol. 8, pp. 4203–16, {{#invoke:doi|main}}
• Bagnall KW 1957, Chemistry of the Rare Radioelements: Polonium-actinium, Butterworths Scientific Publications, London
• Bagnall KW 1966, The Chemistry of Selenium, Tellurium and Polonium, Elsevier, Amsterdam
• Bagnall KW 1990, 'Compounds of Polonium', in KC Buschbeck & C Keller (eds), Gmelin Handbook of Inorganic and Organometallic Chemistry, 8th ed., Po Polonium, Supplement vol. 1, Springer-Verlag, Berlin, pp. 285–340, Template:ISBN
• Bailar JC, Moeller T & Kleinberg J 1965, University Chemistry, DC Heath, Boston
• Bailar JC & Trotman-Dickenson AF 1973, Comprehensive Inorganic Chemistry, vol. 4, Pergamon, Oxford
• Bailar JC, Moeller T, Kleinberg J, Guss CO, Castellion ME & Metz C 1989, Chemistry, 3rd ed., Harcourt Brace Jovanovich, San Diego, Template:ISBN
• Barfuß H, Böhnlein G, Freunek P, Hofmann R, Hohenstein H, Kreische W, Niedrig H and Reimer A 1981, 'The Electric Quadrupole Interaction of ¹¹¹Cd in Arsenic Metal and in the System Sb_1–xIn_x and Sb_1–xCd_x', Hyperfine Interactions, vol. 10, nos 1–4, pp. 967–72, {{#invoke:doi|main}}
• Barnett EdB & Wilson CL 1959, Inorganic Chemistry: A Text-book for Advanced Students, 2nd ed., Longmans, London
• Barrett J 2003, Inorganic Chemistry in Aqueous Solution, The Royal Society of Chemistry, Cambridge, Template:ISBN
• Barsanov GP & Ginzburg AI 1974, 'Mineral', in AM Prokhorov (ed.), Great Soviet Encyclopedia, 3rd ed., vol. 16, Macmillan, New York, pp. 329–32
• Bassett LG, Bunce SC, Carter AE, Clark HM & Hollinger HB 1966, Principles of Chemistry, Prentice-Hall, Englewood Cliffs, New Jersey
• Batsanov SS 1971, 'Quantitative Characteristics of Bond Metallicity in Crystals', Journal of Structural Chemistry, vol. 12, no. 5, pp. 809–13, {{#invoke:doi|main}}
• Baudis U & Fichte R 2012, 'Boron and Boron Alloys', in F Ullmann (ed.), Ullmann's Encyclopedia of Industrial Chemistry, vol. 6, Wiley-VCH, Weinheim, pp. 205–17, {{#invoke:doi|main}}
• Becker WM, Johnson VA & Nussbaum 1971, 'The Physical Properties of Tellurium', in WC Cooper (ed.), Tellurium, Van Nostrand Reinhold, New York
• Belpassi L, Tarantelli F, Sgamellotti A & Quiney HM 2006, 'The Electronic Structure of Alkali Aurides. A Four-Component Dirac−Kohn−Sham study', The Journal of Physical Chemistry A, vol. 110, no. 13, April 6, pp. 4543–54, {{#invoke:doi|main}}
• Berger LI 1997, Semiconductor Materials, CRC Press, Boca Raton, Florida, Template:ISBN
• Bettelheim F, Brown WH, Campbell MK & Farrell SO 2010, Introduction to General, Organic, and Biochemistry, 9th ed., Brooks/Cole, Belmont CA, Template:ISBN
• Bianco E, Butler S, Jiang S, Restrepo OD, Windl W & Goldberger JE 2013, 'Stability and Exfoliation of Germanane: A Germanium Graphane Analogue,' ACS Nano, March 19 (web), {{#invoke:doi|main}}
• Bodner GM & Pardue HL 1993, Chemistry, An Experimental Science, John Wiley & Sons, New York, Template:ISBN
• Bogoroditskii NP & Pasynkov VV 1967, Radio and Electronic Materials, Iliffe Books, London
• Bomgardner MM 2013, 'Thin-Film Solar Firms Revamp To Stay In The Game', Chemical & Engineering News, vol. 91, no. 20, pp. 20–21, {{#if:0009-2347|Template:Catalog lookup link{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}}}}}}}}}}}}}}}}}}}|Template:Error-small}}
• Bond GC 2005, Metal-Catalysed Reactions of Hydrocarbons, Springer, New York, Template:ISBN
• Booth VH & Bloom ML 1972, Physical Science: A Study of Matter and Energy, Macmillan, New York
• Borst KE 1982, 'Characteristic Properties of Metallic Crystals', Journal of Educational Modules for Materials Science and Engineering, vol. 4, no. 3, pp. 457–92, {{#if:0197-3940|Template:Catalog lookup link{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}}}}}}}}}}}}}}}}}}}|Template:Error-small}}
• Boyer RD, Li J, Ogata S & Yip S 2004, 'Analysis of Shear Deformations in Al and Cu: Empirical Potentials Versus Density Functional Theory', Modelling and Simulation in Materials Science and Engineering, vol. 12, no. 5, pp. 1017–29, {{#invoke:doi|main}}
• Bradbury GM, McGill MV, Smith HR & Baker PS 1957, Chemistry and You, Lyons and Carnahan, Chicago
• Bradley D 2014, Resistance is Low: New Quantum Effect, spectroscopyNOW, viewed 15 December 2014-12-15
• Brescia F, Arents J, Meislich H & Turk A 1980, Fundamentals of Chemistry, 4th ed., Academic Press, New York, Template:ISBN
• Brown L & Holme T 2006, Chemistry for Engineering Students, Thomson Brooks/Cole, Belmont California, Template:ISBN
• Brown WP c. 2007 'The Properties of Semi-Metals or Metalloids,' Doc Brown's Chemistry: Introduction to the Periodic Table, viewed 8 February 2013
• Brown TL, LeMay HE, Bursten BE, Murphy CJ, Woodward P 2009, Chemistry: The Central Science, 11th ed., Pearson Education, Upper Saddle River, New Jersey, Template:ISBN
• Brownlee RB, Fuller RW, Hancock WJ, Sohon MD & Whitsit JE 1943, Elements of Chemistry, Allyn and Bacon, Boston
• Brownlee RB, Fuller RT, Whitsit JE Hancock WJ & Sohon MD 1950, Elements of Chemistry, Allyn and Bacon, Boston
• Bucat RB (ed.) 1983, Elements of Chemistry: Earth, Air, Fire & Water, vol. 1, Australian Academy of Science, Canberra, Template:ISBN
• Büchel KH (ed.) 1983, Chemistry of Pesticides, John Wiley & Sons, New York, Template:ISBN
• Büchel KH, Moretto H-H, Woditsch P 2003, Industrial Inorganic Chemistry, 2nd ed., Wiley-VCH, Template:ISBN
• Burkhart CN, Burkhart CG & Morrell DS 2011, 'Treatment of Tinea Versicolor', in HI Maibach & F Gorouhi (eds), Evidence Based Dermatology, 2nd ed., People's Medical Publishing House, Shelton, CT, pp. 365–72, Template:ISBN
• Burrows A, Holman J, Parsons A, Pilling G & Price G 2009, Chemistry³: Introducing Inorganic, Organic and Physical Chemistry, Oxford University, Oxford, Template:ISBN
• Butterman WC & Carlin JF 2004, Mineral Commodity Profiles: Antimony, US Geological Survey
• Butterman WC & Jorgenson JD 2005, Mineral Commodity Profiles: Germanium, US Geological Survey
• Calderazzo F, Ercoli R & Natta G 1968, 'Metal Carbonyls: Preparation, Structure, and Properties', in I Wender & P Pino (eds), Organic Syntheses via Metal Carbonyls: Volume 1, Interscience Publishers, New York, pp. 1–272
• Carapella SC 1968a, 'Arsenic' in CA Hampel (ed.), The Encyclopedia of the Chemical Elements, Reinhold, New York, pp. 29–32
• Carapella SC 1968, 'Antimony' in CA Hampel (ed.), The Encyclopedia of the Chemical Elements, Reinhold, New York, pp. 22–25
• Carlin JF 2011, Minerals Year Book: Antimony, United States Geological Survey
• Carmalt CJ & Norman NC 1998, 'Arsenic, Antimony and Bismuth: Some General Properties and Aspects of Periodicity', in NC Norman (ed.), Chemistry of Arsenic, Antimony and Bismuth, Blackie Academic & Professional, London, pp. 1–38, Template:ISBN
• Carter CB & Norton MG 2013, Ceramic Materials: Science and Engineering, 2nd ed., Springer Science+Business Media, New York, Template:ISBN
• Cegielski C 1998, Yearbook of Science and the Future, Encyclopædia Britannica, Chicago, Template:ISBN
• Chalmers B 1959, Physical Metallurgy, John Wiley & Sons, New York
• Champion J, Alliot C, Renault E, Mokili BM, Chérel M, Galland N & Montavon G 2010, 'Astatine Standard Redox Potentials and Speciation in Acidic Medium', The Journal of Physical Chemistry A, vol. 114, no. 1, pp. 576–82, {{#invoke:doi|main}}
• Chang R 2002, Chemistry, 7th ed., McGraw Hill, Boston, Template:ISBN
• Chao MS & Stenger VA 1964, 'Some Physical Properties of Highly Purified Bromine', Talanta, vol. 11, no. 2, pp. 271–81, {{#invoke:doi|main}}
• Charlier J-C, Gonze X, Michenaud J-P 1994, First-principles Study of the Stacking Effect on the Electronic Properties of Graphite(s), Carbon, vol. 32, no. 2, pp. 289–99, {{#invoke:doi|main}}
• Chatt J 1951, 'Metal and Metalloid Compounds of the Alkyl Radicals', in EH Rodd (ed.), Chemistry of Carbon Compounds: A Modern Comprehensive Treatise, vol. 1, part A, Elsevier, Amsterdam, pp. 417–58
• Chedd G 1969, Half-Way Elements: The Technology of Metalloids, Doubleday, New York
• Chizhikov DM & Shchastlivyi VP 1968, Selenium and Selenides, translated from the Russian by EM Elkin, Collet's, London
• Chizhikov DM & Shchastlivyi 1970, Tellurium and the Tellurides, Collet's, London
• Choppin GR & Johnsen RH 1972, Introductory Chemistry, Addison-Wesley, Reading, Massachusetts
• Chopra IS, Chaudhuri S, Veyan JF & Chabal YJ 2011, 'Turning Aluminium into a Noble-metal-like Catalyst for Low-temperature Activation of Molecular Hydrogen', Nature Materials, vol. 10, pp. 884–89, {{#invoke:doi|main}}
• Chung DDL 2010, Composite Materials: Science and Applications, 2nd ed., Springer-Verlag, London, Template:ISBN
• Clark GL 1960, The Encyclopedia of Chemistry, Reinhold, New York
• Cobb C & Fetterolf ML 2005, The Joy of Chemistry, Prometheus Books, New York, Template:ISBN
• Cohen ML & Chelikowsky JR 1988, Electronic Structure and Optical Properties of Semiconductors, Springer Verlag, Berlin, Template:ISBN
• Coles BR & Caplin AD 1976, The Electronic Structures of Solids, Edward Arnold, London, Template:ISBN
• Conkling JA & Mocella C 2011, Chemistry of Pyrotechnics: Basic Principles and Theory, 2nd ed., CRC Press, Boca Raton, FL, Template:ISBN
• Considine DM & Considine GD (eds) 1984, 'Metalloid', in Van Nostrand Reinhold Encyclopedia of Chemistry, 4th ed., Van Nostrand Reinhold, New York, Template:ISBN
• Cooper DG 1968, The Periodic Table, 4th ed., Butterworths, London
• Corbridge DEC 2013, Phosphorus: Chemistry, Biochemistry and Technology, 6th ed., CRC Press, Boca Raton, Florida, Template:ISBN
• Corwin CH 2005, Introductory Chemistry: Concepts & Connections, 4th ed., Prentice Hall, Upper Saddle River, New Jersey, Template:ISBN
• Cotton FA, Wilkinson G & Gaus P 1995, Basic Inorganic Chemistry, 3rd ed., John Wiley & Sons, New York, Template:ISBN
• Cotton FA, Wilkinson G, Murillo CA & Bochmann 1999, Advanced Inorganic Chemistry, 6th ed., John Wiley & Sons, New York, Template:ISBN
• Cox PA 1997, The Elements: Their Origin, Abundance and Distribution, Oxford University, Oxford, Template:ISBN
• Cox PA 2004, Inorganic Chemistry, 2nd ed., Instant Notes series, Bios Scientific, London, Template:ISBN
• Craig PJ, Eng G & Jenkins RO 2003, 'Occurrence and Pathways of Organometallic Compounds in the Environment – General Considerations' in PJ Craig (ed.), Organometallic Compounds in the Environment, 2nd ed., John Wiley & Sons, Chichester, West Sussex, pp. 1–56, Template:ISBN
• Craig PJ & Maher WA 2003, 'Organoselenium compounds in the environment', in Organometallic Compounds in the Environment, PJ Craig (ed.), John Wiley & Sons, New York, pp. 391–98, Template:ISBN
• Crow JM 2011, 'Boron Carbide Could Light Way to Less-toxic Green Pyrotechnics', Nature News, 8 April, {{#invoke:doi|main}}
• Cusack N 1967, The Electrical and Magnetic Properties of Solids: An Introductory Textbook, 5th ed., John Wiley & Sons, New York
• Cusack N E 1987, The Physics of Structurally Disordered Matter: An Introduction, A Hilger in association with the University of Sussex Press, Bristol, Template:ISBN
• Daintith J (ed.) 2004, Oxford Dictionary of Chemistry, 5th ed., Oxford University, Oxford, Template:ISBN
• Danaith J (ed.) 2008, Oxford Dictionary of Chemistry, Oxford University Press, Oxford, Template:ISBN
• Daniel-Hoffmann M, Sredni B & Nitzan Y 2012, 'Bactericidal Activity of the Organo-Tellurium Compound AS101 Against Enterobacter Cloacae', Journal of Antimicrobial Chemotherapy, vol. 67, no. 9, pp. 2165–72, {{#invoke:doi|main}}
• Daub GW & Seese WS 1996, Basic Chemistry, 7th ed., Prentice Hall, New York, Template:ISBN
• Davidson DF & Lakin HW 1973, 'Tellurium', in DA Brobst & WP Pratt (eds), United States Mineral Resources, Geological survey professional paper 820, United States Government Printing Office, Washington, pp. 627–30
• Dávila ME, Molotov SL, Laubschat C & Asensio MC 2002, 'Structural Determination of Yb Single-Crystal Films Grown on W(110) Using Photoelectron Diffraction', Physical Review B, vol. 66, no. 3, p. 035411–18, {{#invoke:doi|main}}
• Demetriou MD, Launey ME, Garrett G, Schramm JP, Hofmann DC, Johnson WL & Ritchie RO 2011, 'A Damage-Tolerant Glass', Nature Materials, vol. 10, February, pp. 123–28, {{#invoke:doi|main}}
• Deming HG 1925, General Chemistry: An Elementary Survey, 2nd ed., John Wiley & Sons, New York
• Denniston KJ, Topping JJ & Caret RL 2004, General, Organic, and Biochemistry, 5th ed., McGraw-Hill, New York, Template:ISBN
• Deprez N & McLachan DS 1988, 'The Analysis of the Electrical Conductivity of Graphite Conductivity of Graphite Powders During Compaction', Journal of Physics D: Applied Physics, vol. 21, no. 1, {{#invoke:doi|main}}
• Desai PD, James HM & Ho CY 1984, 'Electrical Resistivity of Aluminum and Manganese', Journal of Physical and Chemical Reference Data, vol. 13, no. 4, pp. 1131–72, {{#invoke:doi|main}}
• Desch CH 1914, Intermetallic Compounds, Longmans, Green and Co., New York
• Detty MR & O'Regan MB 1994, Tellurium-Containing Heterocycles, (The Chemistry of Heterocyclic Compounds, vol. 53), John Wiley & Sons, New York
• Dev N 2008, 'Modelling Selenium Fate and Transport in Great Salt Lake Wetlands', PhD dissertation, University of Utah, ProQuest, Ann Arbor, Michigan, Template:ISBN
• De Zuane J 1997, Handbook of Drinking Water Quality, 2nd ed., John Wiley & Sons, New York, Template:ISBN
• Di Pietro P 2014, Optical Properties of Bismuth-Based Topological Insulators, Springer International Publishing, Cham, Switzerland, Template:ISBN
• Divakar C, Mohan M & Singh AK 1984, 'The Kinetics of Pressure-Induced Fcc-Bcc Transformation in Ytterbium', Journal of Applied Physics, vol. 56, no. 8, pp. 2337–40, {{#invoke:doi|main}}
• Donohue J 1982, The Structures of the Elements, Robert E. Krieger, Malabar, Florida, Template:ISBN
• Douglade J & Mercier R 1982, 'Structure Cristalline et Covalence des Liaisons dans le Sulfate d'Arsenic(III), As₂(SO₄)₃', Acta Crystallographica Section B, vol. 38, no. 3, pp. 720–23, {{#invoke:doi|main}}
• Du Y, Ouyang C, Shi S & Lei M 2010, 'Ab Initio Studies on Atomic and Electronic Structures of Black Phosphorus', Journal of Applied Physics, vol. 107, no. 9, pp. 093718–1–4, {{#invoke:doi|main}}
• Dunlap BD, Brodsky MB, Shenoy GK & Kalvius GM 1970, 'Hyperfine Interactions and Anisotropic Lattice Vibrations of ²³⁷Np in α-Np Metal', Physical Review B, vol. 1, no. 1, pp. 44–49, {{#invoke:doi|main}}
• Dunstan S 1968, Principles of Chemistry, D. Van Nostrand Company, London
• Dupree R, Kirby DJ & Freyland W 1982, 'N.M.R. Study of Changes in Bonding and the Metal-Non-metal Transition in Liquid Caesium-Antimony Alloys', Philosophical Magazine Part B, vol. 46 no. 6, pp. 595–606, {{#invoke:doi|main}}
• Eagleson M 1994, Concise Encyclopedia Chemistry, Walter de Gruyter, Berlin, Template:ISBN
• Eason R 2007, Pulsed Laser Deposition of Thin Films: Applications-Led Growth of Functional Materials, Wiley-Interscience, New York
• Ebbing DD & Gammon SD 2010, General Chemistry, 9th ed. enhanced, Brooks/Cole, Belmont, California, Template:ISBN
• Eberle SH 1985, 'Chemical Behavior and Compounds of Astatine', pp. 183–209, in Kugler & Keller
• Edwards PP & Sienko MJ 1983, 'On the Occurrence of Metallic Character in the Periodic Table of the Elements', Journal of Chemical Education, vol. 60, no. 9, pp. 691–96, {{#invoke:doi|main}}
• Edwards PP 1999, 'Chemically Engineering the Metallic, Insulating and Superconducting State of Matter' in KR Seddon & M Zaworotko (eds), Crystal Engineering: The Design and Application of Functional Solids, Kluwer Academic, Dordrecht, pp. 409–31, Template:ISBN
• Edwards PP 2000, 'What, Why and When is a metal?', in N Hall (ed.), The New Chemistry, Cambridge University, Cambridge, pp. 85–114, Template:ISBN
• Edwards PP, Lodge MTJ, Hensel F & Redmer R 2010, '... A Metal Conducts and a Non-metal Doesn't', Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, vol. 368, pp. 941–65, {{#invoke:doi|main}}
• Eggins BR 1972, Chemical Structure and Reactivity, MacMillan, London, Template:ISBN
• Eichler R, Aksenov NV, Belozerov AV, Bozhikov GA, Chepigin VI, Dmitriev SN, Dressler R, Gäggeler HW, Gorshkov VA, Haenssler F, Itkis MG, Laube A, Lebedev VY, Malyshev ON, Oganessian YT, Petrushkin OV, Piguet D, Rasmussen P, Shishkin SV, Shutov, AV, Svirikhin AI, Tereshatov EE, Vostokin GK, Wegrzecki M & Yeremin AV 2007, 'Chemical Characterization of Element 112,' Nature, vol. 447, pp. 72–75, {{#invoke:doi|main}}
• Ellern H 1968, Military and Civilian Pyrotechnics, Chemical Publishing Company, New York
• Emeléus HJ & Sharpe AG 1959, Advances in Inorganic Chemistry and Radiochemistry, vol. 1, Academic Press, New York
• Emsley J 1971, The Inorganic Chemistry of the Non-metals, Methuen Educational, London, Template:ISBN
• Emsley J 2001, Nature's Building Blocks: An A–Z guide to the Elements, Oxford University Press, Oxford, Template:ISBN
• Eranna G 2011, Metal Oxide Nanostructures as Gas Sensing Devices, Taylor & Francis, Boca Raton, Florida, Template:ISBN
• Evans KA 1993, 'Properties and Uses of Oxides and Hydroxides,' in AJ Downs (ed.), Chemistry of Aluminium, Gallium, Indium, and Thallium, Blackie Academic & Professional, Bishopbriggs, Glasgow, pp. 248–91, Template:ISBN
• Evans RC 1966, An Introduction to Crystal Chemistry, Cambridge University, Cambridge
• Everest DA 1953, 'The Chemistry of Bivalent Germanium Compounds. Part IV. Formation of Germanous Salts by Reduction with Hydrophosphorous Acid.' Journal of the Chemical Society, pp. 4117–20, {{#invoke:doi|main}}
• EVM (Expert Group on Vitamins and Minerals) 2003, Safe Upper Levels for Vitamins and Minerals, UK Food Standards Agency, London, Template:ISBN
• Farandos NM, Yetisen AK, Monteiro MJ, Lowe CR & Yun SH 2014, 'Contact Lens Sensors in Ocular Diagnostics', Advanced Healthcare Materials, {{#invoke:doi|main}}, viewed 23 November 2014
• Fehlner TP 1992, 'Introduction', in TP Fehlner (ed.), Inorganometallic chemistry, Plenum, New York, pp. 1–6, Template:ISBN
• Fehlner TP 1990, 'The Metallic Face of Boron,' in AG Sykes (ed.), Advances in Inorganic Chemistry, vol. 35, Academic Press, Orlando, pp. 199–233
• Feng & Jin 2005, Introduction to Condensed Matter Physics: Volume 1, World Scientific, Singapore, Template:ISBN
• Fernelius WC 1982, 'Polonium', Journal of Chemical Education, vol. 59, no. 9, pp. 741–42, {{#invoke:doi|main}}
• Ferro R & Saccone A 2008, Intermetallic Chemistry, Elsevier, Oxford, p. 233, Template:ISBN
• Fesquet AA 1872, A Practical Guide for the Manufacture of Metallic Alloys, trans. A. Guettier, Henry Carey Baird, Philadelphia
• Fine LW & Beall H 1990, Chemistry for Engineers and Scientists, Saunders College Publishing, Philadelphia, Template:ISBN
• Fokwa BPT 2014, 'Borides: Solid-state Chemistry', in Encyclopedia of Inorganic and Bioinorganic Chemistry, John Wiley and Sons, {{#invoke:doi|main}}
• Foster W 1936, The Romance of Chemistry, D Appleton-Century, New York
• Foster LS & Wrigley AN 1958, 'Periodic Table', in GL Clark, GG Hawley & WA Hamor (eds), The Encyclopedia of Chemistry (Supplement), Reinhold, New York, pp. 215–20
• Friend JN 1953, Man and the Chemical Elements, 1st ed., Charles Scribner's Sons, New York
• Fritz JS & Gjerde DT 2008, Ion Chromatography, John Wiley & Sons, New York, Template:ISBN
• Gary S 2013, 'Poisoned Alloy' the Metal of the Future', News in science, viewed 28 August 2013
• Geckeler S 1987, Optical Fiber Transmission Systems, Artech Hous, Norwood, Massachusetts, Template:ISBN
• German Energy Society 2008, Planning and Installing Photovoltaic Systems: A Guide for Installers, Architects and Engineers, 2nd ed., Earthscan, London, Template:ISBN
• Gordh G, Gordh G & Headrick D 2003, A Dictionary of Entomology, CABI Publishing, Wallingford, Template:ISBN
• Gillespie RJ 1998, 'Covalent and Ionic Molecules: Why are BeF2 and AlF3 High Melting Point Solids Whereas BF3 and SiF4 are Gases?', Journal of Chemical Education, vol. 75, no. 7, pp. 923–25, {{#invoke:doi|main}}
• Gillespie RJ & Robinson EA 1963, 'The Sulphuric Acid Solvent System. Part IV. Sulphato Compounds of Arsenic (III)', Canadian Journal of Chemistry, vol. 41, no. 2, pp. 450–58
• Gillespie RJ & Passmore J 1972, 'Polyatomic Cations', Chemistry in Britain, vol. 8, pp. 475–79
• Gladyshev VP & Kovaleva SV 1998, 'Liquidus Shape of the Mercury–Gallium System', Russian Journal of Inorganic Chemistry, vol. 43, no. 9, pp. 1445–46
• Glazov VM, Chizhevskaya SN & Glagoleva NN 1969, Liquid Semiconductors, Plenum, New York
• Glinka N 1965, General Chemistry, trans. D Sobolev, Gordon & Breach, New York
• Glockling F 1969, The Chemistry of Germanium, Academic, London
• Glorieux B, Saboungi ML & Enderby JE 2001, 'Electronic Conduction in Liquid Boron', Europhysics Letters (EPL), vol. 56, no. 1, pp. 81–85, {{#invoke:doi|main}}
• Goldsmith RH 1982, 'Metalloids', Journal of Chemical Education, vol. 59, no. 6, pp. 526–27, {{#invoke:doi|main}}
• Good JM, Gregory O & Bosworth N 1813, 'Arsenicum', in Pantologia: A New Cyclopedia ... of Essays, Treatises, and Systems ... with a General Dictionary of Arts, Sciences, and Words ... , Kearsely, London
• Goodrich BG 1844, A Glance at the Physical Sciences, Bradbury, Soden & Co., Boston
• Gray T 2009, The Elements: A Visual Exploration of Every Known Atom in the Universe, Black Dog & Leventhal, New York, Template:ISBN
• Gray T 2010, 'Metalloids (7)', viewed 8 February 2013
• Gray T, Whitby M & Mann N 2011, Mohs Hardness of the Elements, viewed 12 Feb 2012
• Greaves GN, Knights JC & Davis EA 1974, 'Electronic Properties of Amorphous Arsenic', in J Stuke & W Brenig (eds), Amorphous and Liquid Semiconductors: Proceedings, vol. 1, Taylor & Francis, London, pp. 369–74, Template:ISBN
• Greenwood NN 2001, 'Main Group Element Chemistry at the Millennium', Journal of the Chemical Society, Dalton Transactions, issue 14, pp. 2055–66, {{#invoke:doi|main}}
• Greenwood NN & Earnshaw A 2002, Chemistry of the Elements, 2nd ed., Butterworth-Heinemann, Template:ISBN
• Guan PF, Fujita T, Hirata A, Liu YH & Chen MW 2012, 'Structural Origins of the Excellent Glass-forming Ability of Pd₄₀Ni₄₀P₂₀', Physical Review Letters, vol. 108, no. 17, pp. 175501–1–5, {{#invoke:doi|main}}
• Gunn G (ed.) 2014, Critical Metals Handbook,John Wiley & Sons, Chichester, West Sussex, Template:ISBN
• Gupta VB, Mukherjee AK & Cameotra SS 1997, 'Poly(ethylene Terephthalate) Fibres', in MN Gupta & VK Kothari (eds), Manufactured Fibre Technology, Springer Science+Business Media, Dordrecht, pp. 271–317, Template:ISBN
• Haaland A, Helgaker TU, Ruud K & Shorokhov DJ 2000, 'Should Gaseous BF3 and SiF4 be Described as Ionic Compounds?', Journal of Chemical Education, vol. 77, no.8, pp. 1076–80, {{#invoke:doi|main}}
• Hager T 2006, The Demon under the Microscope, Three Rivers Press, New York, Template:ISBN
• Hai H, Jun H, Yong-Mei L, He-Yong H, Yong C & Kang-Nian F 2012, 'Graphite Oxide as an Efficient and Durable Metal-free Catalyst for Aerobic Oxidative Coupling of Amines to Imines', Green Chemistry, vol. 14, pp. 930–34, {{#invoke:doi|main}}
• Haiduc I & Zuckerman JJ 1985, Basic Organometallic Chemistry, Walter de Gruyter, Berlin, Template:ISBN
• Haissinsky M & Coche A 1949, 'New Experiments on the Cathodic Deposition of Radio-elements', Journal of the Chemical Society, pp. S397–400
• Manson SS & Halford GR 2006, Fatigue and Durability of Structural Materials, ASM International, Materials Park, OH, Template:ISBN
• Haller EE 2006, 'Germanium: From its Discovery to SiGe Devices', Materials Science in Semiconductor Processing, vol. 9, nos 4–5, {{#invoke:doi|main}}, viewed 8 February 2013
• Hamm DI 1969, Fundamental Concepts of Chemistry, Meredith Corporation, New York, Template:ISBN
• Hampel CA & Hawley GG 1966, The Encyclopedia of Chemistry, 3rd ed., Van Nostrand Reinhold, New York
• Hampel CA (ed.) 1968, The Encyclopedia of the Chemical Elements, Reinhold, New York
• Hampel CA & Hawley GG 1976, Glossary of Chemical Terms, Van Nostrand Reinhold, New York, Template:ISBN
• Harding C, Johnson DA & Janes R 2002, Elements of the p Block, Royal Society of Chemistry, Cambridge, Template:ISBN
• Hasan H 2009, The Boron Elements: Boron, Aluminum, Gallium, Indium, Thallium, The Rosen Publishing Group, New York, Template:ISBN
• Hatcher WH 1949, An Introduction to Chemical Science, John Wiley & Sons, New York
• Hawkes SJ 1999, 'Polonium and Astatine are not Semimetals', Chem 13 News, February, p. 14, {{#if:0703-1157|Template:Catalog lookup link{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}}}}}}}}}}}}}}}}}}}|Template:Error-small}}
• Hawkes SJ 2001, 'Semimetallicity', Journal of Chemical Education, vol. 78, no. 12, pp. 1686–87, {{#invoke:doi|main}}
• Hawkes SJ 2010, 'Polonium and Astatine are not Semimetals', Journal of Chemical Education, vol. 87, no. 8, p. 783, {{#invoke:doi|main}}
• Haynes WM (ed.) 2012, CRC Handbook of Chemistry and Physics, 93rd ed., CRC Press, Boca Raton, Florida, Template:ISBN
• He M, Kravchyk K, Walter M & Kovalenko MV 2014, 'Monodisperse Antimony Nanocrystals for High-Rate Li-ion and Na-ion Battery Anodes: Nano versus Bulk', Nano Letters, vol. 14, no. 3, pp. 1255–62, {{#invoke:doi|main}}
• Henderson M 2000, Main Group Chemistry, The Royal Society of Chemistry, Cambridge, Template:ISBN
• Hermann A, Hoffmann R & Ashcroft NW 2013, 'Condensed Astatine: Monatomic and Metallic', Physical Review Letters, vol. 111, pp. 11604–1−11604-5, {{#invoke:doi|main}}
• Hérold A 2006, 'An Arrangement of the Chemical Elements in Several Classes Inside the Periodic Table According to their Common Properties', Comptes Rendus Chimie, vol. 9, no. 1, pp. 148–53, {{#invoke:doi|main}}
• Herzfeld K 1927, 'On Atomic Properties Which Make an Element a Metal', Physical Review, vol. 29, no. 5, pp. 701–05, {{#invoke:doi|main}}
• Hill G & Holman J 2000, Chemistry in Context, 5th ed., Nelson Thornes, Cheltenham, Template:ISBN
• Hiller LA & Herber RH 1960, Principles of Chemistry, McGraw-Hill, New York
• Hindman JC 1968, 'Neptunium', in CA Hampel (ed.), The Encyclopedia of the Chemical Elements, Reinhold, New York, pp. 432–37
• Hoddeson L 2007, 'In the Wake of Thomas Kuhn's Theory of Scientific Revolutions: The Perspective of an Historian of Science,' in S Vosniadou, A Baltas & X Vamvakoussi (eds), Reframing the Conceptual Change Approach in Learning and Instruction, Elsevier, Amsterdam, pp. 25–34, Template:ISBN
• Holderness A & Berry M 1979, Advanced Level Inorganic Chemistry, 3rd ed., Heinemann Educational Books, London, Template:ISBN
• Holt, Rinehart & Wilson c. 2007 'Why Polonium and Astatine are not Metalloids in HRW texts', viewed 8 February 2013
• Hopkins BS & Bailar JC 1956, General Chemistry for Colleges, 5th ed., D. C. Heath, Boston
• Horvath 1973, 'Critical Temperature of Elements and the Periodic System', Journal of Chemical Education, vol. 50, no. 5, pp. 335–36, {{#invoke:doi|main}}
• Hosseini P, Wright CD & Bhaskaran H 2014, 'An optoelectronic framework enabled by low-dimensional phase-change films,' Nature, vol. 511, pp. 206–11, {{#invoke:doi|main}}
• Houghton RP 1979, Metal Complexes in Organic Chemistry, Cambridge University Press, Cambridge, Template:ISBN
• House JE 2008, Inorganic Chemistry, Academic Press (Elsevier), Burlington, Massachusetts, Template:ISBN
• House JE & House KA 2010, Descriptive Inorganic Chemistry, 2nd ed., Academic Press, Burlington, Massachusetts, Template:ISBN
• Housecroft CE & Sharpe AG 2008, Inorganic Chemistry, 3rd ed., Pearson Education, Harlow, Template:ISBN
• Hultgren HH 1966, 'Metalloids', in GL Clark & GG Hawley (eds), The Encyclopedia of Inorganic Chemistry, 2nd ed., Reinhold Publishing, New York
• Hunt A 2000, The Complete A-Z Chemistry Handbook, 2nd ed., Hodder & Stoughton, London, Template:ISBN
• Inagaki M 2000, New Carbons: Control of Structure and Functions, Elsevier, Oxford, Template:ISBN
• IUPAC 1959, Nomenclature of Inorganic Chemistry, 1st ed., Butterworths, London
• IUPAC 1971, Nomenclature of Inorganic Chemistry, 2nd ed., Butterworths, London, Template:ISBN
• IUPAC 2005, Nomenclature of Inorganic Chemistry (the "Red Book"), NG Connelly & T Damhus eds, RSC Publishing, Cambridge, Template:ISBN
• IUPAC 2006–, Compendium of Chemical Terminology (the "Gold Book"), 2nd ed., by M Nic, J Jirat & B Kosata, with updates compiled by A Jenkins, Template:ISBN, {{#invoke:doi|main}}
• James M, Stokes R, Ng W & Moloney J 2000, Chemical Connections 2: VCE Chemistry Units 3 & 4, John Wiley & Sons, Milton, Queensland, Template:ISBN
• Jaouen G & Gibaud S 2010, 'Arsenic-based Drugs: From Fowler's solution to Modern Anticancer Chemotherapy', Medicinal Organometallic Chemistry, vol. 32, pp. 1–20, {{#invoke:doi|main}}
• Jaskula BW 2013, Mineral Commodity Profiles: Gallium, US Geological Survey
• Jenkins GM & Kawamura K 1976, Polymeric Carbons – Carbon Fibre, Glass and Char, Cambridge University Press, Cambridge, Template:ISBN
• Jezequel G & Thomas J 1997, 'Experimental Band Structure of Semimetal Bismuth', Physical Review B, vol. 56, no. 11, pp. 6620–26, {{#invoke:doi|main}}
• Johansen G & Mackintosh AR 1970, 'Electronic Structure and Phase Transitions in Ytterbium', Solid State Communications, vol. 8, no. 2, pp. 121–24
• Jolly WL & Latimer WM 1951, 'The Heat of Oxidation of Germanous Iodide and the Germanium Oxidation Potentials', University of California Radiation Laboratory, Berkeley
• Jolly WL 1966, The Chemistry of the Non-metals, Prentice-Hall, Englewood Cliffs, New Jersey
• Jones BW 2010, Pluto: Sentinel of the Outer Solar System, Cambridge University, Cambridge, Template:ISBN
• Kaminow IP & Li T 2002 (eds), Optical Fiber Telecommunications, Volume IVA, Academic Press, San Diego, Template:ISBN
• Karabulut M, Melnik E, Stefan R, Marasinghe GK, Ray CS, Kurkjian CR & Day DE 2001, 'Mechanical and Structural Properties of Phosphate Glasses', Journal of Non-Crystalline Solids, vol. 288, nos. 1–3, pp. 8–17, {{#invoke:doi|main}}
• Kauthale SS, Tekali SU, Rode AB, Shinde SV, Ameta KL & Pawar RP 2015, 'Silica Sulfuric Acid: A Simple and Powerful Heterogenous Catalyst in Organic Synthesis', in KL Ameta & A Penoni, Heterogeneous Catalysis: A Versatile Tool for the Synthesis of Bioactive Heterocycles, CRC Press, Boca Raton, Florida, pp. 133–62, Template:ISBN
• Kaye GWC & Laby TH 1973, Tables of Physical and Chemical Constants, 14th ed., Longman, London, Template:ISBN
• Keall JHH, Martin NH & Tunbridge RE 1946, 'A Report of Three Cases of Accidental Poisoning by Sodium Tellurite', British Journal of Industrial Medicine, vol. 3, no. 3, pp. 175–76
• Keevil D 1989, 'Aluminium', in MN Patten (ed.), Information Sources in Metallic Materials, Bowker–Saur, London, pp. 103–19, Template:ISBN
• Keller C 1985, 'Preface', in Kugler & Keller
• Kelter P, Mosher M & Scott A 2009, Chemistry: the Practical Science, Houghton Mifflin, Boston, Template:ISBN
• Kennedy T, Mullane E, Geaney H, Osiak M, O'Dwyer C & Ryan KM 2014, 'High-Performance Germanium Nanowire-Based Lithium-Ion Battery Anodes Extending over 1000 Cycles Through in Situ Formation of a Continuous Porous Network', Nano-letters, vol. 14, no. 2, pp. 716–23, {{#invoke:doi|main}}
• Kent W 1950, Kent's Mechanical Engineers' Handbook, 12th ed., vol. 1, John Wiley & Sons, New York
• King EL 1979, Chemistry, Painter Hopkins, Sausalito, California, Template:ISBN
• King RB 1994, 'Antimony: Inorganic Chemistry', in RB King (ed), Encyclopedia of Inorganic Chemistry, John Wiley, Chichester, pp. 170–75, Template:ISBN
• King RB 2004, 'The Metallurgist's Periodic Table and the Zintl-Klemm Concept', in DH Rouvray & RB King (eds), The Periodic Table: Into the 21st Century, Research Studies Press, Baldock, Hertfordshire, pp. 191–206, Template:ISBN
• Kinjo R, Donnadieu B, Celik MA, Frenking G & Bertrand G 2011, 'Synthesis and Characterization of a Neutral Tricoordinate Organoboron Isoelectronic with Amines', Science, pp. 610–13, {{#invoke:doi|main}}
• Kitaĭgorodskiĭ AI 1961, Organic Chemical Crystallography, Consultants Bureau, New York
• Kleinberg J, Argersinger WJ & Griswold E 1960, Inorganic Chemistry, DC Health, Boston
• Klement W, Willens RH & Duwez P 1960, 'Non-Crystalline Structure in Solidified Gold–Silicon Alloys', Nature, vol. 187, pp. 869–70, {{#invoke:doi|main}}
• Klemm W 1950, 'Einige Probleme aus der Physik und der Chemie der Halbmetalle und der Metametalle', Angewandte Chemie, vol. 62, no. 6, pp. 133–42
• Klug HP & Brasted RC 1958, Comprehensive Inorganic Chemistry: The Elements and Compounds of Group IV A, Van Nostrand, New York
• Kneen WR, Rogers MJW & Simpson P 1972, Chemistry: Facts, Patterns, and Principles, Addison-Wesley, London, Template:ISBN
• Kohl AL & Nielsen R 1997, Gas Purification, 5th ed., Gulf Valley Publishing, Houston, Texas, Template:ISBN
• Kolobov AV & Tominaga J 2012, Chalcogenides: Metastability and Phase Change Phenomena, Springer-Verlag, Heidelberg, Template:ISBN
• Kolthoff IM & Elving PJ 1978, Treatise on Analytical Chemistry. Analytical Chemistry of Inorganic and Organic Compounds: Antimony, Arsenic, Boron, Carbon, Molybenum, Tungsten, Wiley Interscience, New York, Template:ISBN
• Kondrat'ev SN & Mel'nikova SI 1978, 'Preparation and Various Characteristics of Boron Hydrogen Sulfates', Russian Journal of Inorganic Chemistry, vol. 23, no. 6, pp. 805–07
• Kopp JG, Lipták BG & Eren H 000, 'Magnetic Flowmeters', in BG Lipták (ed.), Instrument Engineers' Handbook, 4th ed., vol. 1, Process Measurement and Analysis, CRC Press, Boca Raton, Florida, pp. 208–24, Template:ISBN
• Korenman IM 1959, 'Regularities in Properties of Thallium', Journal of General Chemistry of the USSR, English translation, Consultants Bureau, New York, vol. 29, no. 2, pp. 1366–90, {{#if:0022-1279|Template:Catalog lookup link{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}}}}}}}}}}}}}}}}}}}|Template:Error-small}}
• Kosanke KL, Kosanke BJ & Dujay RC 2002, 'Pyrotechnic Particle Morphologies—Metal Fuels', in Selected Pyrotechnic Publications of K.L. and B.J. Kosanke Part 5 (1998 through 2000), Journal of Pyrotechnics, Whitewater, CO, Template:ISBN
• Kotz JC, Treichel P & Weaver GC 2009, Chemistry and Chemical Reactivity, 7th ed., Brooks/Cole, Belmont, California, Template:ISBN
• Kozyrev PT 1959, 'Deoxidized Selenium and the Dependence of its Electrical Conductivity on Pressure. II', Physics of the Solid State, translation of the journal Solid State Physics (Fizika tverdogo tela) of the Academy of Sciences of the USSR, vol. 1, pp. 102–10
• Kraig RE, Roundy D & Cohen ML 2004, 'A Study of the Mechanical and Structural Properties of Polonium', Solid State Communications, vol. 129, issue 6, Feb, pp. 411–13, {{#invoke:doi|main}}
• Krannich LK & Watkins CL 2006, 'Arsenic: Organoarsenic chemistry,' Encyclopedia of inorganic chemistry, viewed 12 Feb 2012 {{#invoke:doi|main}}
• Kreith F & Goswami DY (eds) 2005, The CRC Handbook of Mechanical Engineering, 2nd ed., Boca Raton, Florida, Template:ISBN
• Krishnan S, Ansell S, Felten J, Volin K & Price D 1998, 'Structure of Liquid Boron', Physical Review Letters, vol. 81, no. 3, pp. 586–89, {{#invoke:doi|main}}
• Kross B 2011, 'What's the melting point of steel?', Questions and Answers, Thomas Jefferson National Accelerator Facility, Newport News, VA
• Kudryavtsev AA 1974, The Chemistry & Technology of Selenium and Tellurium, translated from the 2nd Russian edition and revised by EM Elkin, Collet's, London, Template:ISBN
• Kugler HK & Keller C (eds) 1985, Gmelin Handbook of Inorganic and Organometallic chemistry, 8th ed., 'At, Astatine', system no. 8a, Springer-Verlag, Berlin, Template:ISBN
• Ladd M 1999, Crystal Structures: Lattices and Solids in Stereoview, Horwood Publishing, Chichester, Template:ISBN
• Le Bras M, Wilkie CA & Bourbigot S (eds) 2005, Fire Retardancy of Polymers: New Applications of Mineral Fillers, Royal Society of Chemistry, Cambridge, Template:ISBN
• Lee J, Lee EK, Joo W, Jang Y, Kim B, Lim JY, Choi S, Ahn SJ, Ahn JR, Park M, Yang C, Choi BL, Hwang S & Whang D 2014, 'Wafer-Scale Growth of Single-Crystal Monolayer Graphene on Reusable Hydrogen-Terminated Germanium', Science, vol. 344, no. 6181, pp. 286–89, {{#invoke:doi|main}}
• Legit D, Friák M & Šob M 2010, 'Phase Stability, Elasticity, and Theoretical Strength of Polonium from First Principles,' Physical Review B, vol. 81, pp. 214118–1–19, {{#invoke:doi|main}}
• Lehto Y & Hou X 2011, Chemistry and Analysis of Radionuclides: Laboratory Techniques and Methodology, Wiley-VCH, Weinheim, Template:ISBN
• Lewis RJ 1993, Hawley's Condensed Chemical Dictionary, 12th ed., Van Nostrand Reinhold, New York, Template:ISBN
• Li XP 1990, 'Properties of Liquid Arsenic: A Theoretical Study', Physical Review B, vol. 41, no. 12, pp. 8392–406, {{#invoke:doi|main}}
• Lide DR (ed.) 2005, 'Section 14, Geophysics, Astronomy, and Acoustics; Abundance of Elements in the Earth's Crust and in the Sea', in CRC Handbook of Chemistry and Physics, 85th ed., CRC Press, Boca Raton, FL, pp. 14–17, Template:ISBN
• Lidin RA 1996, Inorganic Substances Handbook, Begell House, New York, Template:ISBN
• Lindsjö M, Fischer A & Kloo L 2004, 'Sb8(GaCl4)2: Isolation of a Homopolyatomic Antimony Cation', Angewandte Chemie, vol. 116, no. 19, pp. 2594–97, {{#invoke:doi|main}}
• Lipscomb CA 1972 Pyrotechnics in the '70's A Materials Approach, Naval Ammunition Depot, Research and Development Department, Crane, IN
• Lister MW 1965, Oxyacids, Oldbourne Press, London
• Liu ZK, Jiang J, Zhou B, Wang ZJ, Zhang Y, Weng HM, Prabhakaran D, Mo S-K, Peng H, Dudin P, Kim T, Hoesch M, Fang Z, Dai X, Shen ZX, Feng DL, Hussain Z & Chen YL 2014, 'A Stable Three-dimensional Topological Dirac Semimetal Cd₃As₂', Nature Materials, vol. 13, pp. 677–81, {{#invoke:doi|main}}
• Locke EG, Baechler RH, Beglinger E, Bruce HD, Drow JT, Johnson KG, Laughnan DG, Paul BH, Rietz RC, Saeman JF & Tarkow H 1956, 'Wood', in RE Kirk & DF Othmer (eds), Encyclopedia of Chemical Technology, vol. 15, The Interscience Encyclopedia, New York, pp. 72–102
• Löffler JF, Kündig AA & Dalla Torre FH 2007, 'Rapid Solidification and Bulk Metallic Glasses—Processing and Properties,' in JR Groza, JF Shackelford, EJ Lavernia EJ & MT Powers (eds), Materials Processing Handbook, CRC Press, Boca Raton, Florida, pp. 17–1–44, Template:ISBN
• Long GG & Hentz FC 1986, Problem Exercises for General Chemistry, 3rd ed., John Wiley & Sons, New York, Template:ISBN
• Lovett DR 1977, Semimetals & Narrow-Bandgap Semi-conductors, Pion, London, Template:ISBN
• Lutz J, Schlangenotto H, Scheuermann U, De Doncker R 2011, Semiconductor Power Devices: Physics, Characteristics, Reliability, Springer-Verlag, Berlin, Template:ISBN
• Masters GM & Ela W 2008, Introduction to Environmental Engineering and Science, 3rd ed., Prentice Hall, Upper Saddle River, New Jersey, Template:ISBN
• MacKay KM, MacKay RA & Henderson W 2002, Introduction to Modern Inorganic Chemistry, 6th ed., Nelson Thornes, Cheltenham, Template:ISBN
• MacKenzie D, 2015 'Gas! Gas! Gas!', New Scientist, vol. 228, no. 3044, pp. 34–37
• Madelung O 2004, Semiconductors: Data Handbook, 3rd ed., Springer-Verlag, Berlin, Template:ISBN
• Maeder T 2013, 'Review of Bi₂O₃ Based Glasses for Electronics and Related Applications, International Materials Reviews, vol. 58, no. 1, pp. 3‒40, {{#invoke:doi|main}}
• Mahan BH 1965, University Chemistry, Addison-Wesley, Reading, Massachusetts
• Mainiero C,2014, 'Picatinny chemist wins Young Scientist Award for work on smoke grenades', U.S. Army, Picatinny Public Affairs, 2 April, viewed 9 June 2017
• Manahan SE 2001, Fundamentals of Environmental Chemistry, 2nd ed., CRC Press, Boca Raton, Florida, Template:ISBN
• Mann JB, Meek TL & Allen LC 2000, 'Configuration Energies of the Main Group Elements', Journal of the American Chemical Society, vol. 122, no. 12, pp. 2780–83, {{#invoke:doi|main}}
• Marezio M & Licci F 2000, 'Strategies for Tailoring New Superconducting Systems', in X Obradors, F Sandiumenge & J Fontcuberta (eds), Applied Superconductivity 1999: Large scale applications, volume 1 of Applied Superconductivity 1999: Proceedings of EUCAS 1999, the Fourth European Conference on Applied Superconductivity, held in Sitges, Spain, 14–17 September 1999, Institute of Physics, Bristol, pp. 11–16, Template:ISBN
• Marković N, Christiansen C & Goldman AM 1998, 'Thickness-Magnetic Field Phase Diagram at the Superconductor-Insulator Transition in 2D', Physical Review Letters, vol. 81, no. 23, pp. 5217–20, {{#invoke:doi|main}}
• Massey AG 2000, Main Group Chemistry, 2nd ed., John Wiley & Sons, Chichester, Template:ISBN
• Masterton WL & Slowinski EJ 1977, Chemical Principles, 4th ed., W. B. Saunders, Philadelphia, Template:ISBN
• Matula RA 1979, 'Electrical Resistivity of Copper, Gold, Palladium, and Silver,' Journal of Physical and Chemical Reference Data, vol. 8, no. 4, pp. 1147–298, {{#invoke:doi|main}}
• McKee DW 1984, 'Tellurium – An Unusual Carbon Oxidation Catalyst', Carbon, vol. 22, no. 6, {{#invoke:doi|main}}, pp. 513–16
• McMurray J & Fay RC 2009, General Chemistry: Atoms First, Prentice Hall, Upper Saddle River, New Jersey, Template:ISBN
• McQuarrie DA & Rock PA 1987, General Chemistry, 3rd ed., WH Freeman, New York, Template:ISBN
• Mellor JW 1964, A Comprehensive Treatise on Inorganic and Theoretical Chemistry, vol. 9, John Wiley, New York
• Mellor JW 1964a, A Comprehensive Treatise on Inorganic and Theoretical Chemistry, vol. 11, John Wiley, New York
• Mendeléeff DI 1897, The Principles of Chemistry, vol. 2, 5th ed., trans. G Kamensky, AJ Greenaway (ed.), Longmans, Green & Co., London
• Meskers CEM, Hagelüken C & Van Damme G 2009, 'Green Recycling of EEE: Special and Precious Metal EEE', in SM Howard, P Anyalebechi & L Zhang (eds), Proceedings of Sessions and Symposia Sponsored by the Extraction and Processing Division (EPD) of The Minerals, Metals and Materials Society (TMS), held during the TMS 2009 Annual Meeting & Exhibition San Francisco, California, February 15–19, 2009, The Minerals, Metals and Materials Society, Warrendale, Pennsylvania, Template:ISBN, pp. 1131–36
• Metcalfe HC, Williams JE & Castka JF 1974, Modern Chemistry, Holt, Rinehart and Winston, New York, Template:ISBN
• Meyer JS, Adams WJ, Brix KV, Luoma SM, Mount DR, Stubblefield WA & Wood CM (eds) 2005, Toxicity of Dietborne Metals to Aquatic Organisms, Proceedings from the Pellston Workshop on Toxicity of Dietborne Metals to Aquatic Organisms, 27 July–1 August 2002, Fairmont Hot Springs, British Columbia, Canada, Society of Environmental Toxicology and Chemistry, Pensacola, Florida, Template:ISBN
• Mhiaoui S, Sar F, Gasser J 2003, 'Influence of the History of a Melt on the Electrical Resistivity of Cadmium–Antimony Liquid Alloys', Intermetallics, vol. 11, nos 11–12, pp. 1377–82, {{#invoke:doi|main}}
• Miller GJ, Lee C & Choe W 2002, 'Structure and Bonding Around the Zintl border', in G Meyer, D Naumann & L Wesermann (eds), Inorganic chemistry highlights, Wiley-VCH, Weinheim, pp. 21–53, Template:ISBN
• Millot F, Rifflet JC, Sarou-Kanian V & Wille G 2002, 'High-Temperature Properties of Liquid Boron from Contactless Techniques', International Journal of Thermophysics, vol. 23, no. 5, pp. 1185–95, {{#invoke:doi|main}}
• Mingos DMP 1998, Essential Trends in Inorganic Chemistry, Oxford University, Oxford, Template:ISBN
• Moeller T 1954, Inorganic Chemistry: An Advanced Textbook, John Wiley & Sons, New York
• Mokhatab S & Poe WA 2012, Handbook of Natural Gas Transmission and Processing, 2nd ed., Elsevier, Kidlington, Oxford, Template:ISBN
• Molina-Quiroz RC, Muñoz-Villagrán CM, de la Torre E, Tantaleán JC, Vásquez CC & Pérez-Donoso JM 2012, 'Enhancing the Antibiotic Antibacterial Effect by Sub Lethal Tellurite Concentrations: Tellurite and Cefotaxime Act Synergistically in Escherichia Coli', PloS (Public Library of Science) ONE, vol. 7, no. 4, {{#invoke:doi|main}}
• Monconduit L, Evain M, Boucher F, Brec R & Rouxel J 1992, 'Short Te ... Te Bonding Contacts in a New Layered Ternary Telluride: Synthesis and crystal structure of 2D Nb₃Ge_xTe₆ (x ≃ 0.9)', Zeitschrift für Anorganische und Allgemeine Chemie, vol. 616, no. 10, pp. 177–82, {{#invoke:doi|main}}
• Moody B 1991, Comparative Inorganic Chemistry, 3rd ed., Edward Arnold, London, Template:ISBN
• Moore LJ, Fassett JD, Travis JC, Lucatorto TB & Clark CW 1985, 'Resonance-Ionization Mass Spectrometry of Carbon', Journal of the Optical Society of America B, vol. 2, no. 9, pp. 1561–65, {{#invoke:doi|main}}
• Moore JE 2010, 'The Birth of Topological Insulators,' Nature, vol. 464, pp. 194–98, {{#invoke:doi|main}}
• Moore JE 2011, Topological insulators, IEEE Spectrum, viewed 15 December 2014
• Moore JT 2011, Chemistry for Dummies, 2nd ed., John Wiley & Sons, New York, Template:ISBN
• Moore NC 2014, '45-year Physics Mystery Shows a Path to Quantum Transistors', Michigan News, viewed 17 December 2014
• Morgan WC 1906, Qualitative Analysis as a Laboratory Basis for the Study of General Inorganic Chemistry, The Macmillan Company, New York
• Morita A 1986, 'Semiconducting Black Phosphorus', Journal of Applied Physics A, vol. 39, no. 4, pp. 227–42, {{#invoke:doi|main}}
• Moss TS 1952, Photoconductivity in the Elements, London, Butterworths
• Muncke J 2013, 'Antimony Migration from PET: New Study Investigates Extent of Antimony Migration from Polyethylene Terephthalate (PET) Using EU Migration Testing Rules', Food Packaging Forum, April 2
• Murray JF 1928, 'Cable-Sheath Corrosion', Electrical World, vol. 92, Dec 29, pp. 1295–97, {{#if:0013-4457|Template:Catalog lookup link{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}}}}}}}}}}}}}}}}}}}|Template:Error-small}}
• Nagao T, Sadowski1 JT, Saito M, Yaginuma S, Fujikawa Y, Kogure T, Ohno T, Hasegawa Y, Hasegawa S & Sakurai T 2004, 'Nanofilm Allotrope and Phase Transformation of Ultrathin Bi Film on Si(111)-7×7', Physical Review Letters, vol. 93, no. 10, pp. 105501–1–4, {{#invoke:doi|main}}
• Neuburger MC 1936, 'Gitterkonstanten für das Jahr 1936' (in German), Zeitschrift für Kristallographie, vol. 93, pp. 1–36, {{#if:0044-2968|Template:Catalog lookup link{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}}}}}}}}}}}}}}}}}}}|Template:Error-small}}
• Nickless G 1968, Inorganic Sulphur Chemistry, Elsevier, Amsterdam
• Nielsen FH 1998, 'Ultratrace Elements in Nutrition: Current Knowledge and Speculation', The Journal of Trace Elements in Experimental Medicine, vol. 11, pp. 251–74, {{#invoke:doi|main}}
• NIST (National Institute of Standards and Technology) 2010, Ground Levels and Ionization Energies for Neutral Atoms, by WC Martin, A Musgrove, S Kotochigova & JE Sansonetti, viewed 8 February 2013
• National Research Council 1984, The Competitive Status of the U.S. Electronics Industry: A Study of the Influences of Technology in Determining International Industrial Competitive Advantage, National Academy Press, Washington, DC, Template:ISBN
• New Scientist 1975, 'Chemistry on the Islands of Stability', 11 Sep, p. 574, {{#if:1032-1233|Template:Catalog lookup link{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}}}}}}}}}}}}}}}}}}}|Template:Error-small}}
• New Scientist 2014, 'Colour-changing metal to yield thin, flexible displays', vol. 223, no. 2977
• Oderberg DS 2007, Real Essentialism, Routledge, New York, Template:ISBN
• Oxford English Dictionary 1989, 2nd ed., Oxford University, Oxford, Template:ISBN
• Oganov AR, Chen J, Gatti C, Ma Y, Ma Y, Glass CW, Liu Z, Yu T, Kurakevych OO & Solozhenko VL 2009, 'Ionic High-Pressure Form of Elemental Boron', Nature, vol. 457, 12 Feb, pp. 863–68, {{#invoke:doi|main}}
• Oganov AR 2010, 'Boron Under Pressure: Phase Diagram and Novel High Pressure Phase,' in N Ortovoskaya N & L Mykola L (eds), Boron Rich Solids: Sensors, Ultra High Temperature Ceramics, Thermoelectrics, Armor, Springer, Dordrecht, pp. 207–25, Template:ISBN
• Ogata S, Li J & Yip S 2002, 'Ideal Pure Shear Strength of Aluminium and Copper', Science, vol. 298, no. 5594, 25 October, pp. 807–10, {{#invoke:doi|main}}
• O'Hare D 1997, 'Inorganic intercalation compounds' in DW Bruce & D O'Hare (eds), Inorganic materials, 2nd ed., John Wiley & Sons, Chichester, pp. 171–254, Template:ISBN
• Okajima Y & Shomoji M 1972, Viscosity of Dilute Amalgams', Transactions of the Japan Institute of Metals, vol. 13, no. 4, pp. 255–58, {{#if:0021-4434|Template:Catalog lookup link{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}}}}}}}}}}}}}}}}}}}|Template:Error-small}}
• Oldfield JE, Allaway WH, HA Laitinen, HW Lakin & OH Muth 1974, 'Tellurium', in Geochemistry and the Environment, Volume 1: The Relation of Selected Trace Elements to Health and Disease, US National Committee for Geochemistry, Subcommittee on the Geochemical Environment in Relation to Health and Disease, National Academy of Sciences, Washington, Template:ISBN
• Oliwenstein L 2011, 'Caltech-Led Team Creates Damage-Tolerant Metallic Glass', California Institute of Technology, 12 January, viewed 8 February 2013
• Olmsted J & Williams GM 1997, Chemistry, the Molecular Science, 2nd ed., Wm C Brown, Dubuque, Iowa, Template:ISBN
• Ordnance Office 1863, The Ordnance Manual for the use of the Officers of the Confederate States Army, 1st ed., Evans & Cogswell, Charleston, SC
• Orton JW 2004, The Story of Semiconductors, Oxford University, Oxford, Template:ISBN
• Owen SM & Brooker AT 1991, A Guide to Modern Inorganic Chemistry, Longman Scientific & Technical, Harlow, Essex, Template:ISBN
• Oxtoby DW, Gillis HP & Campion A 2008, Principles of Modern Chemistry, 6th ed., Thomson Brooks/Cole, Belmont, California, Template:ISBN
• Pan K, Fu Y & Huang T 1964, 'Polarographic Behavior of Germanium(II)-Perchlorate in Perchloric Acid Solutions', Journal of the Chinese Chemical Society, pp. 176–84, {{#invoke:doi|main}}
• Parise JB, Tan K, Norby P, Ko Y & Cahill C 1996, 'Examples of Hydrothermal Titration and Real Time X-ray Diffraction in the Synthesis of Open Frameworks', MRS Proceedings, vol. 453, pp. 103–14, {{#invoke:doi|main}}
• Parish RV 1977, The Metallic Elements, Longman, London, Template:ISBN
• Parkes GD & Mellor JW 1943, Mellor's Nodern Inorganic Chemistry, Longmans, Green and Co., London
• Parry RW, Steiner LE, Tellefsen RL & Dietz PM 1970, Chemistry: Experimental Foundations, Prentice-Hall/Martin Educational, Sydney, Template:ISBN
• Partington 1944, A Text-book of Inorganic Chemistry, 5th ed., Macmillan, London
• Pashaey BP & Seleznev VV 1973, 'Magnetic Susceptibility of Gallium-Indium Alloys in Liquid State', Russian Physics Journal, vol. 16, no. 4, pp. 565–66, {{#invoke:doi|main}}
• Patel MR 2012, Introduction to Electrical Power and Power Electronics CRC Press, Boca Raton, Template:ISBN
• Paul RC, Puri JK, Sharma RD & Malhotra KC 1971, 'Unusual Cations of Arsenic', Inorganic and Nuclear Chemistry Letters, vol. 7, no. 8, pp. 725–28, {{#invoke:doi|main}}
• Pauling L 1988, General Chemistry, Dover Publications, New York, Template:ISBN
• Pearson WB 1972, The Crystal Chemistry and Physics of Metals and Alloys, Wiley-Interscience, New York, Template:ISBN
• Perry DL 2011, Handbook of Inorganic Compounds, 2nd ed., CRC Press, Boca Raton, Florida, Template:ISBN
• Peryea FJ 1998, 'Historical Use of Lead Arsenate Insecticides, Resulting Soil Contamination and Implications for Soil Remediation, Proceedings', 16th World Congress of Soil Science, Montpellier, France, 20–26 August
• Phillips CSG & Williams RJP 1965, Inorganic Chemistry, I: Principles and Non-metals, Clarendon Press, Oxford
• Poojary DM, Borade RB & Clearfield A 1993, 'Structural Characterization of Silicon Orthophosphate', Inorganica Chimica Acta, vol. 208, no. 1, pp. 23–29, {{#invoke:doi|main}}
• Pourbaix M 1974, Atlas of Electrochemical Equilibria in Aqueous Solutions, 2nd English edition, National Association of Corrosion Engineers, Houston, Template:ISBN
• Powell HM & Brewer FM 1938, 'The Structure of Germanous Iodide', Journal of the Chemical Society,, pp. 197–198, {{#invoke:doi|main}}
• Powell P 1988, Principles of Organometallic Chemistry, Chapman and Hall, London, Template:ISBN
• Prakash GKS & Schleyer PvR (eds) 1997, Stable Carbocation Chemistry, John Wiley & Sons, New York, Template:ISBN
• Prudenziati M 1977, IV. 'Characterization of Localized States in β-Rhombohedral Boron', in VI Matkovich (ed.), Boron and Refractory Borides, Springer-Verlag, Berlin, pp. 241–61, Template:ISBN
• Puddephatt RJ & Monaghan PK 1989, The Periodic Table of the Elements, 2nd ed., Oxford University, Oxford, Template:ISBN
• Pyykkö P 2012, 'Relativistic Effects in Chemistry: More Common Than You Thought', Annual Review of Physical Chemistry, vol. 63, pp. 45‒64 (56), {{#invoke:doi|main}}
• Rao CNR & Ganguly P 1986, 'A New Criterion for the Metallicity of Elements', Solid State Communications, vol. 57, no. 1, pp. 5–6, {{#invoke:doi|main}}
• Rao KY 2002, Structural Chemistry of Glasses, Elsevier, Oxford, Template:ISBN
• Rausch MD 1960, 'Cyclopentadienyl Compounds of Metals and Metalloids', Journal of Chemical Education, vol. 37, no. 11, pp. 568–78, {{#invoke:doi|main}}
• Rayner-Canham G & Overton T 2006, Descriptive Inorganic Chemistry, 4th ed., WH Freeman, New York, Template:ISBN
• Rayner-Canham G 2011, 'Isodiagonality in the Periodic Table', Foundations of chemistry, vol. 13, no. 2, pp. 121–29, {{#invoke:doi|main}}
• Reardon M 2005, 'IBM Doubles Speed of Germanium chips', CNET News, August 4, viewed 27 December 2013
• Regnault MV 1853, Elements of Chemistry, vol. 1, 2nd ed., Clark & Hesser, Philadelphia
• Reilly C 2002, Metal Contamination of Food, Blackwell Science, Oxford, Template:ISBN
• Reilly 2004, The Nutritional Trace Metals, Blackwell, Oxford, Template:ISBN
• Restrepo G, Mesa H, Llanos EJ & Villaveces JL 2004, 'Topological Study of the Periodic System', Journal of Chemical Information and Modelling, vol. 44, no. 1, pp. 68–75, {{#invoke:doi|main}}
• Restrepo G, Llanos EJ & Mesa H 2006, 'Topological Space of the Chemical Elements and its Properties', Journal of Mathematical Chemistry, vol. 39, no. 2, pp. 401–16, {{#invoke:doi|main}}
• Řezanka T & Sigler K 2008, 'Biologically Active Compounds of Semi-Metals', Studies in Natural Products Chemistry, vol. 35, pp. 585–606, {{#invoke:doi|main}}
• Richens DT 1997, The Chemistry of Aqua Ions, John Wiley & Sons, Chichester, Template:ISBN
• Rochow EG 1957, The Chemistry of Organometallic Compounds, John Wiley & Sons, New York
• Rochow EG 1966, The Metalloids, DC Heath and Company, Boston
• Rochow EG 1973, 'Silicon', in JC Bailar, HJ Emeléus, R Nyholm & AF Trotman-Dickenson (eds), Comprehensive Inorganic Chemistry, vol. 1, Pergamon, Oxford, pp. 1323–1467, Template:ISBN
• Rochow EG 1977, Modern Descriptive Chemistry, Saunders, Philadelphia, Template:ISBN
• Rodgers G 2011, Descriptive Inorganic, Coordination, & Solid-state Chemistry, Brooks/Cole, Belmont, CA, Template:ISBN
• Roher GS 2001, Structure and Bonding in Crystalline Materials, Cambridge University Press, Cambridge, Template:ISBN
• Rossler K 1985, 'Handling of Astatine', pp. 140–56, in Kugler & Keller
• Rothenberg GB 1976, Glass Technology, Recent Developments, Noyes Data Corporation, Park Ridge, New Jersey, Template:ISBN
• Roza G 2009, Bromine, Rosen Publishing, New York, Template:ISBN
• Rupar PA, Staroverov VN & Baines KM 2008, 'A Cryptand-Encapsulated Germanium(II) Dication', Science, vol. 322, no. 5906, pp. 1360–63, {{#invoke:doi|main}}
• Russell AM & Lee KL 2005, Structure-Property Relations in Nonferrous Metals, Wiley-Interscience, New York, Template:ISBN
• Russell MS 2009, The Chemistry of Fireworks, 2nd ed., Royal Society of Chemistry, Template:ISBN
• Sacks MD 1998, 'Mullitization Behavior of Alpha Alumina Silica Microcomposite Powders', in AP Tomsia & AM Glaeser (eds), Ceramic Microstructures: Control at the Atomic Level, proceedings of the International Materials Symposium on Ceramic Microstructures '96: Control at the Atomic Level, June 24–27, 1996, Berkeley, CA, Plenum Press, New York, pp. 285–302, Template:ISBN
• Salentine CG 1987, 'Synthesis, Characterization, and Crystal Structure of a New Potassium Borate, KB₃O₅•3H₂O', Inorganic Chemistry, vol. 26, no. 1, pp. 128–32, {{#invoke:doi|main}}
• Samsonov GV 1968, Handbook of the Physiochemical Properties of the Elements, I F I/Plenum, New York
• Savvatimskiy AI 2005, 'Measurements of the Melting Point of Graphite and the Properties of Liquid Carbon (a review for 1963–2003)', Carbon, vol. 43, no. 6, pp. 1115–42, {{#invoke:doi|main}}
• Savvatimskiy AI 2009, 'Experimental Electrical Resistivity of Liquid Carbon in the Temperature Range from 4800 to ~20,000 K', Carbon, vol. 47, no. 10, pp. 2322–8, {{#invoke:doi|main}}
• Schaefer JC 1968, 'Boron' in CA Hampel (ed.), The Encyclopedia of the Chemical Elements, Reinhold, New York, pp. 73–81
• Schauss AG 1991, 'Nephrotoxicity and Neurotoxicity in Humans from Organogermanium Compounds and Germanium Dioxide', Biological Trace Element Research, vol. 29, no. 3, pp. 267–80, {{#invoke:doi|main}}
• Schmidbaur H & Schier A 2008, 'A Briefing on Aurophilicity,' Chemical Society Reviews, vol. 37, pp. 1931–51, {{#invoke:doi|main}}
• Schroers J 2013, 'Bulk Metallic Glasses', Physics Today, vol. 66, no. 2, pp. 32–37, {{#invoke:doi|main}}
• Schwab GM & Gerlach J 1967, 'The Reaction of Germanium with Molybdenum(VI) Oxide in the Solid State' (in German), Zeitschrift für Physikalische Chemie, vol. 56, pp. 121–32, {{#invoke:doi|main}}
• Schwartz MM 2002, Encyclopedia of Materials, Parts, and Finishes, 2nd ed., CRC Press, Boca Raton, Florida, Template:ISBN
• Schwietzer GK and Pesterfield LL 2010, The Aqueous Chemistry of the Elements, Oxford University, Oxford, Template:ISBN
• ScienceDaily 2012, 'Recharge Your Cell Phone With a Touch? New nanotechnology converts body heat into power', February 22, viewed 13 January 2013
• Scott EC & Kanda FA 1962, The Nature of Atoms and Molecules: A General Chemistry, Harper & Row, New York
• Secrist JH & Powers WH 1966, General Chemistry, D. Van Nostrand, Princeton, New Jersey
• Segal BG 1989, Chemistry: Experiment and Theory, 2nd ed., John Wiley & Sons, New York, Template:ISBN
• Sekhon BS 2012, 'Metalloid Compounds as Drugs', Research in Pharmaceutical Sciences, vol. 8, no. 3, pp. 145–58, {{#if:1735-9414|Template:Catalog lookup link{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}}}}}}}}}}}}}}}}}}}|Template:Error-small}}
• Sequeira CAC 2011, 'Copper and Copper Alloys', in R Winston Revie (ed.), Uhlig's Corrosion Handbook, 3rd ed., John Wiley & Sons, Hoboken, New Jersey, pp. 757–86, Template:ISBN
• Sharp DWA 1981, 'Metalloids', in Miall's Dictionary of Chemistry, 5th ed, Longman, Harlow, Template:ISBN
• Sharp DWA 1983, The Penguin Dictionary of Chemistry, 2nd ed., Harmondsworth, Middlesex, Template:ISBN
• Shelby JE 2005, Introduction to Glass Science and Technology, 2nd ed., Royal Society of Chemistry, Cambridge, Template:ISBN
• Sidgwick NV 1950, The Chemical Elements and Their Compounds, vol. 1, Clarendon, Oxford
• Siebring BR 1967, Chemistry, MacMillan, New York
• Siekierski S & Burgess J 2002, Concise Chemistry of the Elements, Horwood, Chichester, Template:ISBN
• Silberberg MS 2006, Chemistry: The Molecular Nature of Matter and Change, 4th ed., McGraw-Hill, New York, Template:ISBN
• Simple Memory Art c. 2005, Periodic Table, EVA vinyl shower curtain, San Francisco
• Skinner GRB, Hartley CE, Millar D & Bishop E 1979, 'Possible Treatment for Cold Sores,' British Medical Journal, vol 2, no. 6192, p. 704, {{#invoke:doi|main}}
• Slade S 2006, Elements and the Periodic Table, The Rosen Publishing Group, New York, Template:ISBN
• Science Learning Hub 2009, 'The Essential Elements', The University of Waikato Template:Webarchive, viewed 16 January 2013
• Smith DW 1990, Inorganic Substances: A Prelude to the Study of Descriptive Inorganic Chemistry, Cambridge University, Cambridge, Template:ISBN
• Smith R 1994, Conquering Chemistry, 2nd ed., McGraw-Hill, Sydney, Template:ISBN
• Smith AH, Marshall G, Yuan Y, Steinmaus C, Liaw J, Smith MT, Wood L, Heirich M, Fritzemeier RM, Pegram MD & Ferreccio C 2014, 'Rapid Reduction in Breast Cancer Mortality with Inorganic Arsenic in Drinking Water', "EBioMedicine," {{#invoke:doi|main}}
• Sneader W 2005, Drug Discovery: A History, John Wiley & Sons, New York, Template:ISBN
• Snyder MK 1966, Chemistry: Structure and Reactions, Holt, Rinehart and Winston, New York
• Soverna S 2004, 'Indication for a Gaseous Element 112', in U Grundinger (ed.), GSI Scientific Report 2003, GSI Report 2004–1, p. 187, {{#if:0174-0814|Template:Catalog lookup link{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}{{#if:Template:Trim|{{#ifeq:Template:Yesno-no|yes|Template:Main other|{{#invoke:check isxn|check_issn|Template:Trim|error=Template:Error-smallTemplate:Main other}}}}}}}}}}}}}}}}}}}}}}|Template:Error-small}}
• Steele D 1966, The Chemistry of the Metallic Elements, Pergamon Press, Oxford
• Stein L 1985, 'New Evidence that Radon is a Metalloid Element: Ion-Exchange Reactions of Cationic Radon', Journal of the Chemical Society, Chemical Communications, vol. 22, pp. 1631–32, {{#invoke:doi|main}}
• Stein L 1987, 'Chemical Properties of Radon' in PK Hopke (ed.) 1987, Radon and its Decay products: Occurrence, Properties, and Health Effects, American Chemical Society, Washington DC, pp. 240–51, Template:ISBN
• Steudel R 1977, Chemistry of the Non-metals: With an Introduction to atomic Structure and Chemical Bonding, Walter de Gruyter, Berlin, Template:ISBN
• Steurer W 2007, 'Crystal Structures of the Elements' in JW Marin (ed.), Concise Encyclopedia of the Structure of Materials, Elsevier, Oxford, pp. 127–45, Template:ISBN
• Stevens SD & Klarner A 1990, Deadly Doses: A Writer's Guide to Poisons, Writer's Digest Books, Cincinnati, Ohio, Template:ISBN
• Stoker HS 2010, General, Organic, and Biological Chemistry, 5th ed., Brooks/Cole, Cengage Learning, Belmont California, Template:ISBN
• Stott RW 1956, A Companion to Physical and Inorganic Chemistry, Longmans, Green and Co., London
• Stuke J 1974, 'Optical and Electrical Properties of Selenium', in RA Zingaro & WC Cooper (eds), Selenium, Van Nostrand Reinhold, New York, pp. 174–297, Template:ISBN
• Swalin RA 1962, Thermodynamics of Solids, John Wiley & Sons, New York
• Swift EH & Schaefer WP 1962, Qualitative Elemental Analysis, WH Freeman, San Francisco
• Swink LN & Carpenter GB 1966, 'The Crystal Structure of Basic Tellurium Nitrate, Te₂O₄•HNO₃', Acta Crystallographica, vol. 21, no. 4, pp. 578–83, {{#invoke:doi|main}}
• Szpunar J, Bouyssiere B & Lobinski R 2004, 'Advances in Analytical Methods for Speciation of Trace Elements in the Environment', in AV Hirner & H Emons (eds), Organic Metal and Metalloid Species in the Environment: Analysis, Distribution Processes and Toxicological Evaluation, Springer-Verlag, Berlin, pp. 17–40, Template:ISBN
• Taguena-Martinez J, Barrio RA & Chambouleyron I 1991, 'Study of Tin in Amorphous Germanium', in JA Blackman & J Tagüeña (eds), Disorder in Condensed Matter Physics: A Volume in Honour of Roger Elliott, Clarendon Press, Oxford, Template:ISBN, pp. 139–44
• Taniguchi M, Suga S, Seki M, Sakamoto H, Kanzaki H, Akahama Y, Endo S, Terada S & Narita S 1984, 'Core-Exciton Induced Resonant Photoemission in the Covalent Semiconductor Black Phosphorus', Solid State Communications, vo1. 49, no. 9, pp. 867–70
• Tao SH & Bolger PM 1997, 'Hazard Assessment of Germanium Supplements', Regulatory Toxicology and Pharmacology, vol. 25, no. 3, pp. 211–19, {{#invoke:doi|main}}
• Taylor MD 1960, First Principles of Chemistry, D. Van Nostrand, Princeton, New Jersey
• Thayer JS 1977, 'Teaching Bio-Organometal Chemistry. I. The Metalloids', Journal of Chemical Education, vol. 54, no. 10, pp. 604–06, {{#invoke:doi|main}}
• The Economist 2012, 'Phase-Change Memory: Altered States', Technology Quarterly, September 1
• The American Heritage Science Dictionary 2005, Houghton Mifflin Harcourt, Boston, Template:ISBN
• The Chemical News 1897, 'Notices of Books: A Manual of Chemistry, Theoretical and Practical, by WA Tilden', vol. 75, no. 1951, p. 189
• Thomas S & Visakh PM 2012, Handbook of Engineering and Speciality Thermoplastics: Volume 3: Polyethers and Polyesters, John Wiley & Sons, Hoboken, New Jersey, Template:ISBN
• Tilden WA 1876, Introduction to the Study of Chemical Philosophy, D. Appleton and Co., New York
• Timm JA 1944, General Chemistry, McGraw-Hill, New York
• Tyler Miller G 1987, Chemistry: A Basic Introduction, 4th ed., Wadsworth Publishing Company, Belmont, California, Template:ISBN
• Togaya M 2000, 'Electrical Resistivity of Liquid Carbon at High Pressure', in MH Manghnani, W Nellis & MF.Nicol (eds), Science and Technology of High Pressure, proceedings of AIRAPT-17, Honolulu, Hawaii, 25–30 July 1999, vol. 2, Universities Press, Hyderabad, pp. 871–74, Template:ISBN
• Tom LWC, Elden LM & Marsh RR 2004, 'Topical antifungals', in PS Roland & JA Rutka, Ototoxicity, BC Decker, Hamilton, Ontario, pp. 134–39, Template:ISBN
• Tominaga J 2006, 'Application of Ge–Sb–Te Glasses for Ultrahigh Density Optical Storage', in AV Kolobov (ed.), Photo-Induced Metastability in Amorphous Semiconductors, Wiley-VCH, pp. 327–27, Template:ISBN
• Toy AD 1975, The Chemistry of Phosphorus, Pergamon, Oxford, Template:ISBN
• Träger F 2007, Springer Handbook of Lasers and Optics, Springer, New York, Template:ISBN
• Traynham JG 1989, 'Carbonium Ion: Waxing and Waning of a Name', Journal of Chemical Education, vol. 63, no. 11, pp. 930–33, {{#invoke:doi|main}}
• Trivedi Y, Yung E & Katz DS 2013, 'Imaging in Fever of Unknown Origin', in BA Cunha (ed.), Fever of Unknown Origin, Informa Healthcare USA, New York, pp. 209–28, Template:ISBN
• Turner M 2011, 'German E. Coli Outbreak Caused by Previously Unknown Strain', Nature News, 2 Jun, {{#invoke:doi|main}}
• Turova N 2011, Inorganic Chemistry in Tables, Springer, Heidelberg, Template:ISBN
• Tuthill G 2011, 'Faculty profile: Elements of Great Teaching', The Iolani School Bulletin, Winter, viewed 29 October 2011
• Tyler PM 1948, From the Ground Up: Facts and Figures of the Mineral Industries of the United States, McGraw-Hill, New York
• UCR Today 2011, 'Research Performed in Guy Bertrand's Lab Offers Vast Family of New Catalysts for use in Drug Discovery, Biotechnology', University of California, Riverside, July 28
• Uden PC 2005, 'Speciation of Selenium,' in R Cornelis, J Caruso, H Crews & K Heumann (eds), Handbook of Elemental Speciation II: Species in the Environment, Food, Medicine and Occupational Health, John Wiley & Sons, Chichester, pp. 346–65, Template:ISBN
• United Nuclear Scientific 2014, 'Disk Sources, Standard', viewed 5 April 2014
• US Bureau of Naval Personnel 1965, Shipfitter 3 & 2, US Government Printing Office, Washington
• US Environmental Protection Agency 1988, Ambient Aquatic Life Water Quality Criteria for Antimony (III), draft, Office of Research and Development, Environmental Research Laboratories, Washington
• University of Limerick 2014, 'Researchers make breakthrough in battery technology,' 7 February, viewed 2 March 2014
• University of Utah 2014, New 'Topological Insulator' Could Lead to Superfast Computers, Phys.org, viewed 15 December 2014
• Van Muylder J & Pourbaix M 1974, 'Arsenic', in M Pourbaix (ed.), Atlas of Electrochemical Equilibria in Aqueous Solutions, 2nd ed., National Association of Corrosion Engineers, Houston
• Van der Put PJ 1998, The Inorganic Chemistry of Materials: How to Make Things Out of Elements, Plenum, New York, Template:ISBN
• Van Setten MJ, Uijttewaal MA, de Wijs GA & Groot RA 2007, 'Thermodynamic Stability of Boron: The Role of Defects and Zero Point Motion', Journal of the American Chemical Society, vol. 129, no. 9, pp. 2458–65, {{#invoke:doi|main}}
• Vasáros L & Berei K 1985, 'General Properties of Astatine', pp. 107–28, in Kugler & Keller
• Vernon RE 2013, 'Which Elements Are Metalloids?', Journal of Chemical Education, vol. 90, no. 12, pp. 1703–07, {{#invoke:doi|main}}
• Walker P & Tarn WH 1996, CRC Handbook of Metal Etchants, Boca Raton, FL, Template:ISBN
• Walters D 1982, Chemistry, Franklin Watts Science World series, Franklin Watts, London, Template:ISBN
• Wang Y & Robinson GH 2011, 'Building a Lewis Base with Boron', Science, vol. 333, no. 6042, pp. 530–31, {{#invoke:doi|main}}
• Wanga WH, Dongb C & Shek CH 2004, 'Bulk Metallic Glasses', Materials Science and Engineering Reports, vol. 44, nos 2–3, pp. 45–89, {{#invoke:doi|main}}
• Warren J & Geballe T 1981, 'Research Opportunities in New Energy-Related Materials', Materials Science and Engineering, vol. 50, no. 2, pp. 149–98, {{#invoke:doi|main}}
• Weingart GW 1947, Pyrotechnics, 2nd ed., Chemical Publishing Company, New York
• Wells AF 1984, Structural Inorganic Chemistry, 5th ed., Clarendon, Oxford, Template:ISBN
• Whitten KW, Davis RE, Peck LM & Stanley GG 2007, Chemistry, 8th ed., Thomson Brooks/Cole, Belmont, California, Template:ISBN
• Wiberg N 2001, Inorganic Chemistry, Academic Press, San Diego, Template:ISBN
• Wilkie CA & Morgan AB 2009, Fire Retardancy of Polymeric Materials, CRC Press, Boca Raton, Florida, Template:ISBN
• Witt AF & Gatos HC 1968, 'Germanium', in CA Hampel (ed.), The Encyclopedia of the Chemical Elements, Reinhold, New York, pp. 237–44
• Wogan T 2014, "First experimental evidence of a boron fullerene", Chemistry World, 14 July
• Woodward WE 1948, Engineering Metallurgy, Constable, London
• WPI-AIM (World Premier Institute – Advanced Institute for Materials Research) 2012, 'Bulk Metallic Glasses: An Unexpected Hybrid', AIMResearch, Tohoku University, Sendai, Japan, 30 April
• Wulfsberg G 2000, Inorganic Chemistry, University Science Books, Sausalito California, Template:ISBN
• Xu Y, Miotkowski I, Liu C, Tian J, Nam H, Alidoust N, Hu J, Shih C-K, Hasan M & Chen YP 2014, 'Observation of Topological Surface State Quantum Hall Effect in an Intrinsic Three-dimensional Topological Insulator,' Nature Physics, vol, 10, pp. 956–63, {{#invoke:doi|main}}
• Yacobi BG & Holt DB 1990, Cathodoluminescence Microscopy of Inorganic Solids, Plenum, New York, Template:ISBN
• Yang K, Setyawan W, Wang S, Nardelli MB & Curtarolo S 2012, 'A Search Model for Topological Insulators with High-throughput Robustness Descriptors,' Nature Materials, vol. 11, pp. 614–19, {{#invoke:doi|main}}
• Yasuda E, Inagaki M, Kaneko K, Endo M, Oya A & Tanabe Y 2003, Carbon Alloys: Novel Concepts to Develop Carbon Science and Technology, Elsevier Science, Oxford, pp. 3–11 et seq, Template:ISBN
• Yetter RA 2012, Nanoengineered Reactive Materials and their Combustion and Synthesis, course notes, Princeton-CEFRC Summer School On Combustion, June 25–29, 2012, Penn State University
• Young RV & Sessine S (eds) 2000, World of Chemistry, Gale Group, Farmington Hills, Michigan, Template:ISBN
• Young TF, Finley K, Adams WF, Besser J, Hopkins WD, Jolley D, McNaughton E, Presser TS, Shaw DP & Unrine J 2010, 'What You Need to Know About Selenium', in PM Chapman, WJ Adams, M Brooks, CJ Delos, SN Luoma, WA Maher, H Ohlendorf, TS Presser & P Shaw (eds), Ecological Assessment of Selenium in the Aquatic Environment, CRC, Boca Raton, Florida, pp. 7–45, Template:ISBN
• Zalutsky MR & Pruszynski M 2011, 'Astatine-211: Production and Availability', Current Radiopharmaceuticals, vol. 4, no. 3, pp. 177–85, {{#invoke:doi|main}}
• Zhang GX 2002, 'Dissolution and Structures of Silicon Surface', in MJ Deen, D Misra & J Ruzyllo (eds), Integrated Optoelectronics: Proceedings of the First International Symposium, Philadelphia, PA, The Electrochemical Society, Pennington, NJ, pp. 63–78, Template:ISBN
• Zhang TC, Lai KCK & Surampalli AY 2008, 'Pesticides', in A Bhandari, RY Surampalli, CD Adams, P Champagne, SK Ong, RD Tyagi & TC Zhang (eds), Contaminants of Emerging Environmental Concern, American Society of Civil Engineers, Reston, Virginia, Template:ISBN, pp. 343–415
• Zhdanov GS 1965, Crystal Physics, translated from the Russian publication of 1961 by AF Brown (ed.), Oliver & Boyd, Edinburgh
• Zingaro RA 1994, 'Arsenic: Inorganic Chemistry', in RB King (ed.) 1994, Encyclopedia of Inorganic Chemistry, John Wiley & Sons, Chichester, pp. 192–218, Template:ISBN

Template:Div col end

Further readingEdit

• Brady JE, Humiston GE & Heikkinen H (1980), "Chemistry of the Representative Elements: Part II, The Metalloids and Nonmetals", in General Chemistry: Principles and Structure, 2nd ed., SI version, John Wiley & Sons, New York, pp. 537–91, Template:ISBN
• Chedd G (1969), Half-way Elements: The Technology of Metalloids, Doubleday, New YorkTemplate:ISBN?
• Choppin GR & Johnsen RH (1972), "Group IV and the Metalloids", in Introductory Chemistry, Addison-Wesley, Reading, Massachusetts, pp. 341–57
• Dunstan S (1968), "The Metalloids", in Principles of Chemistry, D. Van Nostrand Company, London, pp. 407–39
• Goldsmith RH (1982), "Metalloids", Journal of Chemical Education, vol. 59, no. 6, pp. 526527, {{#invoke:doi|main}}
• Hawkes SJ (2001), "Semimetallicity", Journal of Chemical Education, vol. 78, no. 12, pp. 1686–87, {{#invoke:doi|main}}
• Metcalfe HC, Williams JE & Castka JF (1974), "Aluminum and the Metalloids", in Modern Chemistry, Holt, Rinehart and Winston, New York, pp. 538–57, Template:ISBN
• Miller JS (2019), "Viewpoint: Metalloids – An Electronic Band Structure Perspective", Chemistry – A European Perspective, preprint version, {{#invoke:doi|main}}
• Moeller T, Bailar JC, Kleinberg J, Guss CO, Castellion ME & Metz C (1989), "Carbon and the Semiconducting Elements", in Chemistry, with Inorganic Qualitative Analysis, 3rd ed., Harcourt Brace Jovanovich, San Diego, pp. 742–75, Template:ISBN
• Parveen N et al. (2020), "Metalloids in plants: A systematic discussion beyond description", Annals of Applied Biology, {{#invoke:doi|main}}
• Rieske M (1998), "Metalloids", in Encyclopedia of Earth and Physical Sciences, Marshall Cavendish, New York, vol. 6, pp. 758–59, Template:ISBN (set)
• Rochow EG (1966), The Metalloids, DC Heath and Company, BostonTemplate:ISBN?
• Vernon RE (2013), "Which Elements are Metalloids?", Journal of Chemical Education, vol. 90, no. 12, pp. 1703–07, {{#invoke:doi|main}}
• —— (2020,) "Organising the Metals and Nonmetals", Foundations of Chemistry, (open access)

{{#invoke:Navbox|navbox}} Template:Periodic table (navbox)

Template:Featured article Template:Authority control