Fullerene

Template:Short description Template:Use dmy dates

Template:Nanomaterials A fullerene is an allotrope of carbon whose molecules consist of carbon atoms connected by single and double bonds so as to form a closed or partially closed mesh, with fused rings of five to six atoms. The molecules may have hollow sphere- and ellipsoid-like forms, tubes, or other shapes.

Fullerenes with a closed mesh topology are informally denoted by their empirical formula C_n, often written Cn, where n is the number of carbon atoms. However, for some values of n there may be more than one isomer.

The family is named after buckminsterfullerene (C₆₀), the most famous member, which in turn is named after Buckminster Fuller. The closed fullerenes, especially C₆₀, are also informally called buckyballs for their resemblance to the standard ball of association football. Nested closed fullerenes have been named bucky onions. Cylindrical fullerenes are also called carbon nanotubes or buckytubes.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> The bulk solid form of pure or mixed fullerenes is called fullerite.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>

Fullerenes had been predicted for some time, but only after their accidental synthesis in 1985 were they detected in nature<ref name="buseck1992">Template:Cite journal</ref><ref name="invWeb2010">{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> and outer space.<ref name="cami2010">Template:Cite journal</ref><ref name="bbc2010">Stars reveal carbon 'spaceballs', BBC, 22 July 2010.</ref> The discovery of fullerenes greatly expanded the number of known allotropes of carbon, which had previously been limited to graphite, diamond, and amorphous carbon such as soot and charcoal. They have been the subject of intense research, both for their chemistry and for their technological applications, especially in materials science, electronics, and nanotechnology.<ref>Template:Cite journal</ref>

DefinitionEdit

IUPAC defines fullerenes as "polyhedral closed cages made up entirely of n three-coordinate carbon atoms and having 12 pentagonal and (n/2-10) hexagonal faces, where n ≥ 20."<ref>Template:Cite journal</ref>

HistoryEdit

Predictions and limited observationsEdit

The icosahedral Template:Chem cage was mentioned in 1965 as a possible topological structure.<ref>Template:Cite journal</ref> Eiji Osawa predicted the existence of Template:Chem in 1970.<ref>Template:Cite journal</ref><ref>Template:Cite journal</ref> He noticed that the structure of a corannulene molecule was a subset of the shape of a football, and hypothesised that a full ball shape could also exist. Japanese scientific journals reported his idea, but neither it nor any translations of it reached Europe or the Americas.

Also in 1970, R.W.Henson (then of the UK Atomic Energy Research Establishment) proposed the Template:Chem structure and made a model of it. Unfortunately, the evidence for that new form of carbon was very weak at the time, so the proposal was met with skepticism, and was never published. It was acknowledged only in 1999.<ref>Template:Cite journal</ref><ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>

In 1973, independently from Henson, D. A. Bochvar and E. G. Galpern made a quantum-chemical analysis of the stability of Template:Chem and calculated its electronic structure. The paper was published in 1973,<ref>Template:Cite journal</ref> but the scientific community did not give much importance to this theoretical prediction.

Around 1980, Sumio Iijima identified the molecule of Template:Chem from an electron microscope image of carbon black, where it formed the core of a particle with the structure of a "bucky onion".<ref>Template:Cite journal</ref>

Also in the 1980s at MIT, Mildred Dresselhaus and Morinobu Endo, collaborating with T. Venkatesan, directed studies blasting graphite with lasers, producing carbon clusters of atoms, which would be later identified as "fullerenes."<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>

Discovery of Template:ChemEdit

In 1985, Harold Kroto of the University of Sussex, working with James R. Heath, Sean O'Brien, Robert Curl and Richard Smalley from Rice University, discovered fullerenes in the sooty residue created by vaporising carbon in a helium atmosphere. In the mass spectrum of the product, discrete peaks appeared corresponding to molecules with the exact mass of sixty or seventy or more carbon atoms, namely Template:Chem and Template:Chem. The team identified their structure as the now familiar "buckyballs".<ref name="kroto1985">Template:Cite journal</ref>

The name "buckminsterfullerene" was eventually chosen for Template:Chem by the discoverers as an homage to American architect Buckminster Fuller for the vague similarity of the structure to the geodesic domes which he popularized; which, if they were extended to a full sphere, would also have the icosahedral symmetry group.<ref>Buckminsterfullerene, Template:Chem. Sussex Fullerene Group. chm.bris.ac.uk</ref> The "ene" ending was chosen to indicate that the carbons are unsaturated, being connected to only three other atoms instead of the normal four. The shortened name "fullerene" eventually came to be applied to the whole family.

Kroto, Curl, and Smalley were awarded the 1996 Nobel Prize in Chemistry<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> for their roles in the discovery of this class of molecules.

Further developmentsEdit

Kroto and the Rice team already discovered other fullerenes besides C₆₀,<ref name=kroto1985/> and the list was much expanded in the following years. Carbon nanotubes were first discovered and synthesized in 1991.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref><ref>Template:Cite journal</ref>

After their discovery, minute quantities of fullerenes were found to be produced in sooty flames,<ref>Template:Cite journal</ref> and by lightning discharges in the atmosphere.<ref name=invWeb2010/> In 1992, fullerenes were found in a family of mineraloids known as shungites in Karelia, Russia.<ref name=buseck1992/>

The production techniques were improved by many scientists, including Donald Huffman, Wolfgang Krätschmer, Lowell D. Lamb, and Konstantinos Fostiropoulos.<ref>Template:Cite journal</ref> Thanks to their efforts, by 1990 it was relatively easy to produce gram-sized samples of fullerene powder. Fullerene purification remains a challenge to chemists and to a large extent determines fullerene prices.

In 2010, the spectral signatures of C₆₀ and C₇₀ were observed by NASA's Spitzer infrared telescope in a cloud of cosmic dust surrounding a star 6500 light years away.<ref name=cami2010/> Kroto commented: "This most exciting breakthrough provides convincing evidence that the buckyball has, as I long suspected, existed since time immemorial in the dark recesses of our galaxy."<ref name=bbc2010/> According to astronomer Letizia Stanghellini, "It’s possible that buckyballs from outer space provided seeds for life on Earth."<ref>Template:Cite news</ref> In 2019, ionized C₆₀ molecules were detected with the Hubble Space Telescope in the space between those stars.<ref name="SA-20190429">Template:Cite news</ref><ref name="AJL-20190422">Template:Cite journal</ref>

TypesEdit

There are two major families of fullerenes, with fairly distinct properties and applications: the closed buckyballs and the open-ended cylindrical carbon nanotubes.<ref name="miess2004">Template:Cite book</ref> However, hybrid structures exist between those two classes, such as carbon nanobuds — nanotubes capped by hemispherical meshes or larger "buckybuds".

BuckyballsEdit

BuckminsterfullereneEdit

{{#invoke:Labelled list hatnote|labelledList|Main article|Main articles|Main page|Main pages}} Buckminsterfullerene is the smallest fullerene molecule containing pentagonal and hexagonal rings in which no two pentagons share an edge (which can be destabilizing, as in pentalene). It is also most common in terms of natural occurrence, as it can often be found in soot.

The empirical formula of buckminsterfullerene is Template:Chem and its structure is a truncated icosahedron, which resembles an association football ball of the type made of twenty hexagons and twelve pentagons, with a carbon atom at the vertices of each polygon and a bond along each polygon edge.

The van der Waals diameter of a buckminsterfullerene molecule is about 1.1 nanometers (nm).<ref>Template:Cite journal</ref> The nucleus to nucleus diameter of a buckminsterfullerene molecule is about 0.71 nm.

The buckminsterfullerene molecule has two bond lengths. The 6:6 ring bonds (between two hexagons) can be considered "double bonds" and are shorter (1.401 Å) than the 6:5 bonds (1.458 Å, between a hexagon and a pentagon). The weighted average bond length is 1.44 Å.<ref>Template:Cite journal</ref>

Other fullerenesEdit

Another fairly common fullerene has empirical formula Template:Chem,<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> but fullerenes with 72, 76, 84 and even up to 100 carbon atoms are commonly obtained.

The smallest possible fullerene is the dodecahedral Template:Chem. There are no fullerenes with 22 vertices.<ref>Template:Cite journal</ref> The number of different fullerenes C_2n grows with increasing n = 12, 13, 14, ..., roughly in proportion to n⁹ (sequence A007894 in the OEIS). For instance, there are 1812 non-isomorphic fullerenes Template:Chem. Note that only one form of Template:Chem, buckminsterfullerene, has no pair of adjacent pentagons (the smallest such fullerene). To further illustrate the growth, there are 214,127,713 non-isomorphic fullerenes Template:Chem, 15,655,672 of which have no adjacent pentagons. Optimized structures of many fullerene isomers are published and listed on the web.<ref>Fowler, P. W. and Manolopoulos, D. E. Template:Chem Fullerenes. nanotube.msu.edu</ref>

Heterofullerenes have heteroatoms substituting carbons in cage or tube-shaped structures. They were discovered in 1993<ref>Harris, D.J. "Discovery of Nitroballs: Research in Fullerene Chemistry" http://www.usc.edu/CSSF/History/1993/CatWin_S05.html Template:Webarchive</ref> and greatly expand the overall fullerene class of compounds and can have dangling bonds on their surfaces. Notable examples include boron, nitrogen (azafullerene), oxygen, and phosphorus derivatives.

Carbon nanotubesEdit

Carbon nanotubes are cylindrical fullerenes. These tubes of carbon are usually only a few nanometres wide, but they can range from less than a micrometer to several millimeters in length. They often have closed ends, but can be open-ended as well. There are also cases in which the tube reduces in diameter before closing off. Their unique molecular structure results in extraordinary macroscopic properties, including high tensile strength, high electrical conductivity, high ductility, high heat conductivity, and relative chemical inactivity (as it is cylindrical and "planar" — that is, it has no "exposed" atoms that can be easily displaced). One proposed use of carbon nanotubes is in paper batteries, developed in 2007 by researchers at Rensselaer Polytechnic Institute.<ref>Template:Cite journal</ref> Another highly speculative proposed use in the field of space technologies is to produce high-tensile carbon cables required by a space elevator.

DerivativesEdit

Buckyballs and carbon nanotubes have been used as building blocks for a great variety of derivatives and larger structures, such as<ref name=miess2004/>

• Nested buckyballs ("carbon nano-onions" or "buckyonions")<ref>Template:Cite journal</ref> proposed for lubricants;<ref>Template:Cite journal</ref>
• Nested carbon nanotubes ("carbon megatubes")<ref>Template:Cite journal</ref>
• Linked "ball-and-chain" dimers (two buckyballs linked by a carbon chain)<ref>Template:Cite journal</ref>
• Rings of buckyballs linked together.<ref>Template:Cite journal</ref>

Heterofullerenes and non-carbon fullerenesEdit

After the discovery of C60, many fullerenes have been synthesized (or studied theoretically by molecular modeling methods) in which some or all the carbon atoms are replaced by other elements. Non-carbon nanotubes, in particular, have attracted much attention.

BoronEdit

A type of buckyball which uses boron atoms, instead of the usual carbon, was predicted and described in 2007. The Template:Chem structure, with each atom forming 5 or 6 bonds, was predicted to be more stable than the Template:Chem buckyball.<ref>Template:Cite journal</ref> However, subsequent analysis found that the predicted I_h symmetric structure was vibrationally unstable and the resulting cage would undergo a spontaneous symmetry break, yielding a puckered cage with rare T_h symmetry (symmetry of a volleyball).<ref>Template:Cite journal</ref> The number of six-member rings in this molecule is 20 and number of five-member rings is 12. There is an additional atom in the center of each six-member ring, bonded to each atom surrounding it. By employing a systematic global search algorithm, it was later found that the previously proposed Template:Chem fullerene is not a global maximum for 80-atom boron clusters and hence can not be found in nature; the most stable configurations have complex geometries.<ref name="de2011">Template:Cite journal</ref> The same paper concluded that boron's energy landscape, unlike others, has many disordered low-energy structures, hence pure boron fullerenes are unlikely to exist in nature.<ref name=de2011/>

However, an irregular Template:Chem complex dubbed borospherene was prepared in 2014. This complex has two hexagonal faces and four heptagonal faces with in D_2d symmetry interleaved with a network of 48 triangles.<ref>Template:Cite journal</ref>

Template:Chem was experimentally obtained in 2024, i.e. 17 years after theoretical prediction by Gonzalez Szwacki et al..<ref>Template:Cite journal</ref>

Other elementsEdit

Inorganic (carbon-free) fullerene-type structures have been built with the molybdenum(IV) sulfide (MoS₂), long used as a graphite-like lubricant, tungsten (WS₂), titanium (TiS₂) and niobium (NbS₂). These materials were found to be stable up to at least 350 tons/cm² (34.3 GPa).<ref>Template:Cite news</ref>

Icosahedral or distorted-icosahedral fullerene-like complexes have also been prepared for germanium, tin, and lead; some of these complexes are spacious enough to hold most transition metal atoms.<ref>Template:Cite journal</ref><ref>Template:Cite journal</ref>

Main fullerenesEdit

Below is a table of main closed carbon fullerenes synthesized and characterized so far, with their CAS number when known.<ref>Template:Cite book</ref> Fullerenes with fewer than 60 carbon atoms have been called "lower fullerenes",<ref>Template:Cite journal</ref> and those with more than 70 atoms "higher fullerenes".<ref>Template:Cite journal</ref>

Formula	Num. Isom.[1]	Mol. Symm.	Cryst. Symm.	Space group	No	Pearson symbol	a (nm)	b (nm)	c (nm)	β°	Z	ρ (g/cm3)
Template:Chem	1	Ih
Template:Chem	1	Ih
[[C70 fullerene|Template:Chem]]	1	D5h
Template:Chem	1	D6h
Template:Chem	1	D3h
Template:Chem	2	D2*	Monoclinic	P21	4	mP2	1.102	1.108	1.768	108.10	2	1.48
			Cubic	FmTemplate:Overlinem	225	cF4	1.5475	1.5475	1.5475	90	4	1.64
Template:Chem	5	D2v
Template:Chem	7
Template:Chem	9	Template:Chem, C2v, C3v	Monoclinic	P21	4	mP2	1.141	1.1355	1.8355	108.07	2
Template:Chem	24	D2*, D2d	Cubic	FmTemplate:Overlinem			1.5817<ref>Template:Cite journal</ref>	1.5817	1.5817	90
Template:Chem	19
Template:Chem	35
Template:Chem	46
Template:Chem

In the table, "Num.Isom." is the number of possible isomers within the "isolated pentagon rule", which states that two pentagons in a fullerene should not share edges.<ref>Template:Cite journal</ref><ref name="died1992">Template:Cite journal</ref> "Mol.Symm." is the symmetry of the molecule,<ref name=died1992/><ref>Template:Cite book</ref> whereas "Cryst.Symm." is that of the crystalline framework in the solid state. Both are specified for the most experimentally abundant form(s). The asterisk * marks symmetries with more than one chiral form.

When Template:Chem or Template:Chem crystals are grown from toluene solution they have a monoclinic symmetry. The crystal structure contains toluene molecules packed between the spheres of the fullerene. However, evaporation of the solvent from Template:Chem transforms it into a face-centered cubic form.<ref>Template:Cite journal</ref> Both monoclinic and face-centered cubic (fcc) phases are known for better-characterized [[buckminsterfullerene|Template:Chem]] and [[C70 fullerene|Template:Chem]] fullerenes.

PropertiesEdit

TopologyEdit

Schlegel diagrams are often used to clarify the 3D structure of closed-shell fullerenes, as 2D projections are often not ideal in this sense.<ref name="iupacful">Template:Cite journal</ref>

In mathematical terms, the combinatorial topology (that is, the carbon atoms and the bonds between them, ignoring their positions and distances) of a closed-shell fullerene with a simple sphere-like mean surface (orientable, genus zero) can be represented as a convex polyhedron; more precisely, its one-dimensional skeleton, consisting of its vertices and edges. The Schlegel diagram is a projection of that skeleton onto one of the faces of the polyhedron, through a point just outside that face; so that all other vertices project inside that face.

• Schlegel diagrams of some fullerenes
• Graph of 20-fullerene w-nodes.svg

  C20
  (dodecahedron)

• Graph of 26-fullerene 5-base w-nodes.svg

  C26

• Graph of 60-fullerene w-nodes.svg

  C60
  (truncated icosahedron)

• Graph of 70-fullerene w-nodes.svg

  C70

The Schlegel diagram of a closed fullerene is a graph that is planar and 3-regular (or "cubic"; meaning that all vertices have degree 3).

A closed fullerene with sphere-like shell must have at least some cycles that are pentagons or heptagons. More precisely, if all the faces have 5 or 6 sides, it follows from Euler's polyhedron formula, V−E+F=2 (where V, E, F are the numbers of vertices, edges, and faces), that V must be even, and that there must be exactly 12 pentagons and V/2−10 hexagons. Similar constraints exist if the fullerene has heptagonal (seven-atom) cycles.<ref>"Fullerene", Encyclopædia Britannica on-line</ref>

BondingEdit

Since each carbon atom is connected to only three neighbors, instead of the usual four, it is customary to describe those bonds as being a mixture of single and double covalent bonds. The hybridization of carbon in C₆₀ has been reported to be sp^2.01.<ref name="Yamada">Template:Cite journal</ref> The bonding state can be analyzed by Raman spectroscopy, IR spectroscopy and X-ray photoelectron spectroscopy.<ref name=Yamada/><ref>Template:Cite journal</ref>

EncapsulationEdit

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

Additional atoms, ions, clusters, or small molecules can be trapped inside fullerenes to form inclusion compounds known as endohedral fullerenes. An unusual example is the egg-shaped fullerene Tb₃N@Template:Chem, which violates the isolated pentagon rule.<ref>Template:Cite journal</ref> Evidence for a meteor impact at the end of the Permian period was found by analyzing noble gases preserved by being trapped in fullerenes.<ref>Template:Cite journal</ref>

ResearchEdit

In the field of nanotechnology, heat resistance and superconductivity are some of the more heavily studied properties.

There are many calculations that have been done using ab-initio quantum methods applied to fullerenes. By DFT and TD-DFT methods one can obtain IR, Raman and UV spectra. Results of such calculations can be compared with experimental results.

Fullerene is an unusual reactant in many organic reactions such as the Bingel reaction discovered in 1993.

AromaticityEdit

Researchers have been able to increase the reactivity of fullerenes by attaching active groups to their surfaces. Buckminsterfullerene does not exhibit "superaromaticity": that is, the electrons in the hexagonal rings do not delocalize over the whole molecule.

A spherical fullerene of n carbon atoms has n pi-bonding electrons, free to delocalize. These should try to delocalize over the whole molecule. The quantum mechanics of such an arrangement should be like only one shell of the well-known quantum mechanical structure of a single atom, with a stable filled shell for n = 2, 8, 18, 32, 50, 72, 98, 128, etc. (i.e., twice a perfect square number), but this series does not include 60. This 2(N + 1)² rule (with N integer) for spherical aromaticity is the three-dimensional analogue of Hückel's rule. The 10+ cation would satisfy this rule, and should be aromatic. This has been shown to be the case using quantum chemical modelling, which showed the existence of strong diamagnetic sphere currents in the cation.<ref>Template:Cite journal</ref>

As a result, Template:Chem in water tends to pick up two more electrons and become an anion. The nTemplate:Chem described below may be the result of Template:Chem trying to form a loose metallic bond.

ReactionsEdit

PolymerizationEdit

Under high pressure and temperature, buckyballs collapse to form various one-, two-, or three-dimensional carbon frameworks. Single-strand polymers are formed using the Atom Transfer Radical Addition Polymerization (ATRAP) route.<ref>Template:Cite journal</ref>

"Ultrahard fullerite" is a coined term frequently used to describe material produced by high-pressure high-temperature (HPHT) processing of fullerite. Such treatment converts fullerite into a nanocrystalline form of diamond which has been reported to exhibit remarkable mechanical properties.<ref>Template:Cite journal</ref>

ChemistryEdit

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

Fullerenes are stable, but not totally unreactive. The sp²-hybridized carbon atoms, which are at their energy minimum in planar graphite, must be bent to form the closed sphere or tube, which produces angle strain. The characteristic reaction of fullerenes is electrophilic addition at 6,6-double bonds, which reduces angle strain by changing sp²-hybridized carbons into sp³-hybridized ones. The change in hybridized orbitals causes the bond angles to decrease from about 120° in the sp² orbitals to about 109.5° in the sp³ orbitals. This decrease in bond angles allows for the bonds to bend less when closing the sphere or tube, and thus, the molecule becomes more stable.

SolubilityEdit

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

Fullerenes are soluble in many organic solvents, such as toluene, chlorobenzene, and 1,2,3-trichloropropane. Solubilities are generally rather low, such as 8 g/L for C₆₀ in carbon disulfide. Still, fullerenes are the only known allotrope of carbon that can be dissolved in common solvents at room temperature.<ref>Template:Cite journal</ref><ref>Template:Cite journal</ref><ref>Template:Cite journal</ref><ref>Template:Cite journal</ref><ref>Template:Cite journal</ref> Among the best solvents is 1-chloronaphthalene, which will dissolve 51 g/L of C₆₀.

Solutions of pure buckminsterfullerene have a deep purple color. Solutions of Template:Chem are a reddish brown. The higher fullerenes Template:Chem to Template:Chem have a variety of colors.

Millimeter-sized crystals of Template:Chem and Template:Chem, both pure and solvated, can be grown from benzene solution. Crystallization of Template:Chem from benzene solution below 30 °C (when solubility is maximum) yields a triclinic solid solvate Template:Chem·4Template:Chem. Above 30 °C one obtains solvate-free fcc Template:Chem.<ref>Template:Cite journal</ref><ref>Template:Cite journal</ref>

Quantum mechanicsEdit

In 1999, researchers from the University of Vienna demonstrated that wave-particle duality applied to molecules such as fullerene.<ref>Template:Cite journal</ref>

SuperconductivityEdit

{{#invoke:Labelled list hatnote|labelledList|Main article|Main articles|Main page|Main pages}} Fullerenes are normally electrical insulators, but when crystallized with alkali metals, the resultant compound can be conducting or even superconducting.<ref>Template:Cite book</ref>

ChiralityEdit

Some fullerenes (e.g. Template:Chem, Template:Chem, Template:Chem, and Template:Chem) are inherently chiral because they are D₂-symmetric, and have been successfully resolved. Research efforts are ongoing to develop specific sensors for their enantiomers.

StabilityEdit

Two theories have been proposed to describe the molecular mechanisms that make fullerenes. The older, "bottom-up" theory proposes that they are built atom-by-atom. The alternative "top-down" approach claims that fullerenes form when much larger structures break into constituent parts.<ref name="kurz">Support for top-down theory of how 'buckyballs’ form. kurzweilai.net. 24 September 2013</ref>

In 2013 researchers discovered that asymmetrical fullerenes formed from larger structures settle into stable fullerenes. The synthesized substance was a particular metallofullerene consisting of 84 carbon atoms with two additional carbon atoms and two yttrium atoms inside the cage. The process produced approximately 100 micrograms.<ref name=kurz/>

However, they found that the asymmetrical molecule could theoretically collapse to form nearly every known fullerene and metallofullerene. Minor perturbations involving the breaking of a few molecular bonds cause the cage to become highly symmetrical and stable. This insight supports the theory that fullerenes can be formed from graphene when the appropriate molecular bonds are severed.<ref name=kurz/><ref>Template:Cite journal</ref>

Systematic namingEdit

According to the IUPAC, to name a fullerene, one must cite the number of member atoms for the rings which comprise the fullerene, its symmetry point group in the Schoenflies notation, and the total number of atoms. For example, buckminsterfullerene C₆₀ is systematically named (Template:Chem-I_h)[5,6]fullerene. The name of the point group should be retained in any derivative of said fullerene, even if that symmetry is lost by the derivation.

To indicate the position of substituted or attached elements, the fullerene atoms are usually numbered in a spiral path, usually starting with the ring on one of the main axes. If the structure of the fullerene does not allow such numbering, another starting atom was chosen to still achieve a spiral path sequence.

The latter is the case for C₇₀, which is (Template:Chem-D_5h(6))[5,6]fullerene in IUPAC notation. The symmetry D_5h(6) means that this is the isomer where the C₅ axis goes through a pentagon surrounded by hexagons rather than pentagons.<ref name=iupacful/>

• Buckminsterfullerene-2D-skeletal numbered.svg

  (Template:Chem-Ih)[5,6]fullerene
  Carbon numbering.

• C70fullerene-2D-skeletal numbered.svg

  (Template:Chem-D_5h(6))[5,6]fullerene
  Carbon numbering.

• C70fullerene-2D-skeletal numbered isobonds.svg

  (Template:Chem-D_5h(6))[5,6]fullerene
  Non-equivalent bonds shown by different colours.

• Cyclopropa12 C70fullerene-2D-skeletal renumbered.svg

  3'H-Cyclopropa[1,2](Template:Chem-D_5h(6))[5,6]fullerene.

• Cyclopropa212 C70fullerene-2D-skeletal renumbered.svg

  3'H-Cyclopropa[2,12](Template:Chem-D_5h(6))[5,6]fullerene.

• PC71BM.svg

  Template:Chem-PCBM, [1,2]-isomer.
  IUPAC name is methyl 4-(3’-phenyl-3’H-cyclopropa[1,2](Template:Chem-D_5h(6))[5,6]fullerene-3’-yl)butyrate.

In IUPAC's nomenclature, fully saturated analogues of fullerenes are called fulleranes. If the mesh has other element(s) substituted for one or more carbons, the compound is named a heterofullerene. If a double bond is replaced by a methylene bridge Template:Chem2, the resulting structure is a homofullerene. If an atom is fully deleted and missing valences saturated with hydrogen atoms, it is a norfullerene. When bonds are removed (both sigma and pi), the compound becomes secofullerene; if some new bonds are added in an unconventional order, it is a cyclofullerene.<ref name="iupacful" />

ProductionEdit

Fullerene production generally starts by producing fullerene-rich soot. The original (and still current) method was to send a large electric current between two nearby graphite electrodes in an inert atmosphere. The resulting electric arc vaporizes the carbon into a plasma that then cools into sooty residue.<ref name=kroto1985/> Alternatively, soot is produced by laser ablation of graphite or pyrolysis of aromatic hydrocarbons.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>Template:Citation needed Combustion of benzene is the most efficient process, developed at MIT.<ref>Template:Cite book</ref><ref name="arika2006">Template:Cite journal</ref>

These processes yield a mixture of various fullerenes and other forms of carbon. The fullerenes are then extracted from the soot using appropriate organic solvents and separated by chromatography.<ref>Template:Cite book</ref>Template:Rp One can obtain milligram quantities of fullerenes with 80 atoms or more. C₇₆, C₇₈ and C₈₄ are available commercially.

ApplicationsEdit

BiomedicalEdit

Functionalized fullerenes have been researched extensively for several potential biomedical applications including high-performance MRI contrast agents, X-ray imaging contrast agents, photodynamic therapy for tumor treatment,<ref>Template:Cite journal</ref><ref>Template:Cite journal</ref> and drug and gene delivery.<ref name="lalwa2013">Template:Cite journal</ref><ref name="Pesado-Gómez 2024">Template:Cite journal</ref>

Safety and toxicityEdit

{{#invoke:Labelled list hatnote|labelledList|Main article|Main articles|Main page|Main pages}} In 2013, a comprehensive review on the toxicity of fullerene was published reviewing work beginning in the early 1990s to present and concluded that very little evidence gathered since the discovery of fullerenes indicate that Template:Chem is toxic.<ref name=lalwa2013/> The toxicity of these carbon nanoparticles is not only dose- and time-dependent, but also depends on a number of other factors such as:

• type (e.g.: Template:Chem, Template:Chem, M@Template:Chem, M@Template:Chem)
• functional groups used to water-solubilize these nanoparticles (e.g.: OH, COOH)
• method of administration (e.g.: intravenous, intraperitoneal)

It was recommended to assess the pharmacology of every new fullerene- or metallofullerene-based complex individually as a different compound.

Popular cultureEdit

Examples of fullerenes appear frequently in popular culture. Fullerenes appeared in fiction well before scientists took serious interest in them. In a humorously speculative 1966 column for New Scientist, David Jones suggested the possibility of making giant hollow carbon molecules by distorting a plane hexagonal net with the addition of impurity atoms.<ref>Template:Cite journal</ref>

See alsoEdit

Template:Div col

• Buckypaper
• Carbocatalysis
• Dodecahedrane
• Fullerene ligand
• Goldberg–Coxeter construction
• Graphene
• Lonsdaleite
• Triumphene
• Truncated rhombic triacontahedron

Template:Div col end

ReferencesEdit

Template:Reflist

External linksEdit

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• Nanocarbon: From Graphene to Buckyballs Interactive 3D models of cyclohexane, benzene, graphene, graphite, chiral & non-chiral nanotubes, and C60 Buckyballs – WeCanFigureThisOut.org.
• Introduction to fullerites
• Giant Fullerenes, a short video looking at Giant Fullerenes

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