Planetary core
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A planetary core consists of the innermost layers of a planet.<ref name="sci.1112328">Template:Cite journal</ref> Cores may be entirely liquid, or a mixture of solid and liquid layers as is the case in the Earth.<ref name="Williams and Nimmo 2004">Template:Cite journal</ref> In the Solar System, core sizes range from about 20% (the Moon) to 85% of a planet's radius (Mercury).
Gas giants also have cores, though the composition of these are still a matter of debate and range in possible composition from traditional stony/iron, to ice or to fluid metallic hydrogen.<ref name="Pollack, et al. 1977">Template:Cite journal</ref><ref name="Fortney and Hubbard 2003">Template:Cite journal</ref><ref name="Stevenson 1982">Template:Cite journal</ref> Gas giant cores are proportionally much smaller than those of terrestrial planets, though they can be considerably larger than the Earth's nevertheless; Jupiter's is 10–30 times heavier than Earth,<ref name="Stevenson 1982" /> and exoplanet HD149026 b may have a core 100 times the mass of the Earth.<ref name="Sato, et al. 2005">Template:Cite journal</ref>
Planetary cores are challenging to study because they are impossible to reach by drill and there are almost no samples that are definitively from the core. Thus, they are studied via indirect techniques such as seismology, mineral physics, and planetary dynamics.
DiscoveryEdit
Earth's coreEdit
{{#invoke:Labelled list hatnote|labelledList|Main article|Main articles|Main page|Main pages}} In 1797, Henry Cavendish calculated the average density of the Earth to be 5.48 times the density of water (later refined to 5.53), which led to the accepted belief that the Earth was much denser in its interior.<ref name="Cavendish 1798">Template:Cite journal</ref> Following the discovery of iron meteorites, Wiechert in 1898 postulated that the Earth had a similar bulk composition to iron meteorites, but the iron had settled to the interior of the Earth, and later represented this by integrating the bulk density of the Earth with the missing iron and nickel as a core.<ref name="Wiechert 1897">Template:Cite journal</ref> The first detection of Earth's core occurred in 1906 by Richard Dixon Oldham upon discovery of the P-wave shadow zone; the liquid outer core.<ref name="Oldham 1906">Template:Cite journal</ref> By 1936 seismologists had determined the size of the overall core as well as the boundary between the fluid outer core and the solid inner core.<ref name="Transdyne Corporation">{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>
Moon's coreEdit
The internal structure of the Moon was characterized in 1974 using seismic data collected by the Apollo missions of moonquakes.<ref>Template:Cite journal</ref> The Moon's core has a radius of 300 km.<ref>Template:Cite journal</ref> The Moon's iron core has a liquid outer layer that makes up 60% of the volume of the core, with a solid inner core.<ref>Template:Cite journal</ref>
Cores of the rocky planetsEdit
The cores of the rocky planets were initially characterized by analyzing data from spacecraft, such as NASA's Mariner 10 that flew by Mercury and Venus to observe their surface characteristics.<ref>Template:Citation</ref> The cores of other planets cannot be measured using seismometers on their surface, so instead they have to be inferred based on calculations from these fly-by observation. Mass and size can provide a first-order calculation of the components that make up the interior of a planetary body. The structure of rocky planets is constrained by the average density of a planet and its moment of inertia.<ref name="solomon 1979">Template:Cite journal</ref> The moment of inertia for a differentiated planet is less than 0.4, because the density of the planet is concentrated in the center.<ref>Template:Cite book</ref> Mercury has a moment of inertia of 0.346, which is evidence for a core.<ref>Template:Cite journal</ref> Conservation of energy calculations as well as magnetic field measurements can also constrain composition, and surface geology of the planets can characterize differentiation of the body since its accretion.<ref>Template:Cite journal</ref> Mercury, Venus, and Mars’ cores are about 75%, 50%, and 40% of their radius respectively.<ref name="de pater 2015">Template:Cite book</ref><ref name="stevenson 2001">Template:Cite journal</ref>
FormationEdit
AccretionEdit
Planetary systems form from flattened disks of dust and gas that accrete rapidly (within thousands of years) into planetesimals around 10 km in diameter. From here gravity takes over to produce Moon to Mars-sized planetary embryos (105 – 106 years) and these develop into planetary bodies over an additional 10–100 million years.<ref name="Wood, Walter and Jonathan 2006">Template:Cite journal</ref>
Jupiter and Saturn most likely formed around previously existing rocky and/or icy bodies, rendering these previous primordial planets into gas-giant cores.<ref name="Stevenson 1982" /> This is the planetary core accretion model of planet formation.
DifferentiationEdit
Planetary differentiation is broadly defined as the development from one thing to many things; homogeneous body to several heterogeneous components.<ref name="Merriam Webster 2014">Template:Cite dictionary</ref> The hafnium-182/tungsten-182 isotopic system has a half-life of 9 million years, and is approximated as an extinct system after 45 million years. Hafnium is a lithophile element and tungsten is siderophile element. Thus if metal segregation (between the Earth's core and mantle) occurred in under 45 million years, silicate reservoirs develop positive Hf/W anomalies, and metal reservoirs acquire negative anomalies relative to undifferentiated chondrite material.<ref name="Wood, Walter and Jonathan 2006" /> The observed Hf/W ratios in iron meteorites constrain metal segregation to under 5 million years, the Earth's mantle Hf/W ratio places Earth's core as having segregated within 25 million years.<ref name="Wood, Walter and Jonathan 2006" /> Several factors control segregation of a metal core including the crystallization of perovskite. Crystallization of perovskite in an early magma ocean is an oxidation process and may drive the production and extraction of iron metal from an original silicate melt.
Core merging and impactsEdit
Impacts between planet-sized bodies in the early Solar System are important aspects in the formation and growth of planets and planetary cores.
Earth–Moon systemEdit
The giant impact hypothesis states that an impact between a theoretical Mars-sized planet Theia and the early Earth formed the modern Earth and Moon.<ref name="Halliday and N. 2000">Template:Cite journal</ref> During this impact the majority of the iron from Theia and the Earth became incorporated into the Earth's core.<ref name="Seti Institute 2012">{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>
MarsEdit
Core merging between the proto-Mars and another differentiated planetoid could have been as fast as 1000 years or as slow as 300,000 years (depending on viscosity of both cores).<ref name="Monteaux and Arkani-Hamed 2013">Template:Cite journal</ref>
ChemistryEdit
Determining primary composition – EarthEdit
Using the chondritic reference model and combining known compositions of the crust and mantle, the unknown component, the composition of the inner and outer core, can be determined: 85% Fe, 5% Ni, 0.9% Cr, 0.25% Co, and all other refractory metals at very low concentration.<ref name="Wood, Walter and Jonathan 2006" /> This leaves Earth's core with a 5–10% weight deficit for the outer core,<ref name="McDonough 2003">Template:Cite journal</ref> and a 4–5% weight deficit for the inner core;<ref name="McDonough 2003" /> which is attributed to lighter elements that should be cosmically abundant and are iron-soluble; H, O, C, S, P, and Si.<ref name="Wood, Walter and Jonathan 2006"/> Earth's core contains half the Earth's vanadium and chromium, and may contain considerable niobium and tantalum.<ref name="McDonough 2003" /> Earth's core is depleted in germanium and gallium.<ref name="McDonough 2003" />
Weight deficit components – EarthEdit
Sulfur is strongly siderophilic and only moderately volatile and depleted in the silicate earth; thus may account for 1.9 weight % of Earth's core.<ref name="Wood, Walter and Jonathan 2006" /> By similar arguments, phosphorus may be present up to 0.2 weight %. Hydrogen and carbon, however, are highly volatile and thus would have been lost during early accretion and therefore can only account for 0.1 to 0.2 weight % respectively.<ref name="Wood, Walter and Jonathan 2006" /> Silicon and oxygen thus make up the remaining mass deficit of Earth's core; though the abundances of each are still a matter of controversy revolving largely around the pressure and oxidation state of Earth's core during its formation.<ref name="Wood, Walter and Jonathan 2006" /> No geochemical evidence exists to include any radioactive elements in Earth's core.<ref name="McDonough 2003" /> Despite this, experimental evidence has found potassium to be strongly siderophilic at the temperatures associated with core formation, thus there is potential for potassium in planetary cores of planets, and therefore potassium-40 as well.<ref name="Murthy, van Westrenen and Fei 2003">Template:Cite journal</ref>
Isotopic composition – EarthEdit
Hafnium/tungsten (Hf/W) isotopic ratios, when compared with a chondritic reference frame, show a marked enrichment in the silicate earth indicating depletion in Earth's core. Iron meteorites, believed to be resultant from very early core fractionation processes, are also depleted.<ref name="Wood, Walter and Jonathan 2006" /> Niobium/tantalum (Nb/Ta) isotopic ratios, when compared with a chondritic reference frame, show mild depletion in bulk silicate Earth and the moon.<ref name="Hauck and Van Orman 2011">Template:Cite journal</ref>
Pallasite meteoritesEdit
Pallasites are thought to form at the core-mantle boundary of an early planetesimal, although a recent hypothesis suggests that they are impact-generated mixtures of core and mantle materials.<ref>Edward R. D. Scott, "Impact Origins for Pallasites," Lunar and Planetary Science XXXVIII, 2007.</ref>
DynamicsEdit
DynamoEdit
Dynamo theory is a proposed mechanism to explain how celestial bodies like the Earth generate magnetic fields. The presence or lack of a magnetic field can help constrain the dynamics of a planetary core. Refer to Earth's magnetic field for further details. A dynamo requires a source of thermal and/or compositional buoyancy as a driving force.<ref name="Hauck and Van Orman 2011" /> Thermal buoyancy from a cooling core alone cannot drive the necessary convection as indicated by modelling, thus compositional buoyancy (from changes of phase) is required. On Earth the buoyancy is derived from crystallization of the inner core (which can occur as a result of temperature). Examples of compositional buoyancy include precipitation of iron alloys onto the inner core and liquid immiscibility both, which could influence convection both positively and negatively depending on ambient temperatures and pressures associated with the host-body.<ref name="Hauck and Van Orman 2011" /> Other celestial bodies that exhibit magnetic fields are Mercury, Jupiter, Ganymede, and Saturn.<ref name="Pollack, et al. 1977" />
Core heat sourceEdit
A planetary core acts as a heat source for the outer layers of a planet. In the Earth, the heat flux over the core mantle boundary is 12 terawatts.<ref name="nimmo 2015">Template:Cite book</ref> This value is calculated from a variety of factors: secular cooling, differentiation of light elements, Coriolis forces, radioactive decay, and latent heat of crystallization.<ref name="nimmo 2015" /> All planetary bodies have a primordial heat value, or the amount of energy from accretion. Cooling from this initial temperature is called secular cooling, and in the Earth the secular cooling of the core transfers heat into an insulating silicate mantle.<ref name="nimmo 2015" /> As the inner core grows, the latent heat of crystallization adds to the heat flux into the mantle.<ref name="nimmo 2015" />
Stability and instabilityEdit
Small planetary cores may experience catastrophic energy release associated with phase changes within their cores. Ramsey (1950) found that the total energy released by such a phase change would be on the order of 1029 joules; equivalent to the total energy release due to earthquakes through geologic time. Such an event could explain the asteroid belt. Such phase changes would only occur at specific mass to volume ratios, and an example of such a phase change would be the rapid formation or dissolution of a solid core component.<ref name="Ramsey 1950">Template:Cite journal</ref>
Trends in the Solar SystemEdit
Inner rocky planetsEdit
All of the rocky inner planets, as well as the moon, have an iron-dominant core. Venus and Mars have an additional major element in the core. Venus’ core is believed to be iron-nickel, similarly to Earth. Mars, on the other hand, is believed to have an iron-sulfur core and is separated into an outer liquid layer around an inner solid core.<ref name="stevenson 2001" /> As the orbital radius of a rocky planet increases, the size of the core relative to the total radius of the planet decreases.<ref name="solomon 1979" /> This is believed to be because differentiation of the core is directly related to a body's initial heat, so Mercury's core is relatively large and active.<ref name="solomon 1979" /> Venus and Mars, as well as the moon, do not have magnetic fields. This could be due to a lack of a convecting liquid layer interacting with a solid inner core, as Venus’ core is not layered.<ref name="de pater 2015" /> Although Mars does have a liquid and solid layer, they do not appear to be interacting in the same way that Earth's liquid and solid components interact to produce a dynamo.<ref name="stevenson 2001" />
Outer gas and ice giantsEdit
Current understanding of the outer planets in the solar system, the ice and gas giants, theorizes small cores of rock surrounded by a layer of ice, and in Jupiter and Saturn models suggest a large region of liquid metallic hydrogen and helium.<ref name="de pater 2015" /> The properties of these metallic hydrogen layers is a major area of contention because it is difficult to produce in laboratory settings, due to the high pressures needed.<ref>Template:Cite journal</ref> Jupiter and Saturn appear to release a lot more energy than they should be radiating just from the sun, which is attributed to heat released by the hydrogen and helium layer. Uranus does not appear to have a significant heat source, but Neptune has a heat source that is attributed to a “hot” formation.<ref name="de pater 2015" />
Observed typesEdit
The following summarizes known information about the planetary cores of given non-stellar bodies.
Within the Solar SystemEdit
MercuryEdit
Mercury has an observed magnetic field, which is believed to be generated within its metallic core.<ref name="Hauck and Van Orman 2011" /> Mercury's core occupies 85% of the planet's radius, making it the largest core relative to the size of the planet in the Solar System; this indicates that much of Mercury's surface may have been lost early in the Solar System's history.<ref name="NASA 2012">Template:Cite journal</ref> Mercury has a solid silicate crust and mantle overlying a solid metallic outer core layer, followed by a deeper liquid core layer, and then a possible solid inner core making a third layer.<ref name="NASA 2012" /> The composition of the iron-rich core remains uncertain, but it likely contains nickel, silicon and perhaps sulfur and carbon, plus trace amounts of other elements.<ref>Template:Cite book</ref>
VenusEdit
The composition of Venus' core varies significantly depending on the model used to calculate it, thus constraints are required.<ref name="Fegley 2003">Template:Cite journal</ref>
| Element | Chondritic Model | Equilibrium Condensation Model | Pyrolitic Model |
|---|---|---|---|
| Iron | 88.6% | 94.4% | 78.7% |
| Nickel | 5.5% | 5.6% | 6.6% |
| Cobalt | 0.26% | Unknown | Unknown |
| Sulfur | 5.1% | 0% | 4.9% |
| Oxygen | 0% | Unknown | 9.8% |
MoonEdit
The existence of a lunar core is still debated; however, if it does have a core it would have formed synchronously with the Earth's own core at 45 million years post-start of the Solar System based on hafnium-tungsten evidence<ref name="Munker, et al. 2003">Template:Cite journal</ref> and the giant impact hypothesis. Such a core may have hosted a geomagnetic dynamo early on in its history.<ref name="Hauck and Van Orman 2011" />
EarthEdit
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The Earth has an observed magnetic field generated within its metallic core.<ref name="Hauck and Van Orman 2011" /> The Earth has a 5–10% mass deficit for the entire core and a density deficit from 4–5% for the inner core.<ref name="McDonough 2003" /> The Fe/Ni value of the core is well constrained by chondritic meteorites.<ref name="McDonough 2003" /> Sulfur, carbon, and phosphorus only account for ~2.5% of the light element component/mass deficit.<ref name="McDonough 2003"/> No geochemical evidence exists for including any radioactive elements in the core.<ref name="McDonough 2003" /> However, experimental evidence has found that potassium is strongly siderophile when dealing with temperatures associated with core-accretion, and thus potassium-40 could have provided an important source of heat contributing to the early Earth's dynamo, though to a lesser extent than on sulfur rich Mars.<ref name="Murthy, van Westrenen and Fei 2003" /> The core contains half the Earth's vanadium and chromium, and may contain considerable niobium and tantalum.<ref name="McDonough 2003" /> The core is depleted in germanium and gallium.<ref name="McDonough 2003"/> Core mantle differentiation occurred within the first 30 million years of Earth's history.<ref name="McDonough 2003" /> Inner core crystallization timing is still largely unresolved.<ref name="McDonough 2003" />
MarsEdit
Mars possibly hosted a core-generated magnetic field in the past.<ref name="Hauck and Van Orman 2011"/> The dynamo ceased within 0.5 billion years of the planet's formation.<ref name="Williams and Nimmo 2004"/> Hf/W isotopes derived from the martian meteorite Zagami, indicate rapid accretion and core differentiation of Mars; i.e. under 10 million years.<ref name="Halliday and N. 2000"/> Potassium-40 could have been a major source of heat powering the early Martian dynamo.<ref name="Murthy, van Westrenen and Fei 2003" />
Core merging between proto-Mars and another differentiated planetoid could have been as fast as 1000 years or as slow as 300,000 years (depending on the viscosity of both cores and mantles).<ref name="Monteaux and Arkani-Hamed 2013" /> Impact-heating of the Martian core would have resulted in stratification of the core and kill the Martian dynamo for a duration between 150 and 200 million years.<ref name="Monteaux and Arkani-Hamed 2013" /> Modelling done by Williams, et al. 2004 suggests that in order for Mars to have had a functional dynamo, the Martian core was initially hotter by 150 K than the mantle (agreeing with the differentiation history of the planet, as well as the impact hypothesis), and with a liquid core potassium-40 would have had opportunity to partition into the core providing an additional source of heat. The model further concludes that the core of mars is entirely liquid, as the latent heat of crystallization would have driven a longer-lasting (greater than one billion years) dynamo.<ref name="Williams and Nimmo 2004"/> If the core of Mars is liquid, the lower bound for sulfur would be five weight %.<ref name="Williams and Nimmo 2004" />
GanymedeEdit
Ganymede has an observed magnetic field generated within its metallic core.<ref name="Hauck and Van Orman 2011" />
JupiterEdit
Jupiter has an observed magnetic field generated within its core, indicating some metallic substance is present.<ref name="Pollack, et al. 1977" /> Its magnetic field is the strongest in the Solar System after the Sun's.
Jupiter has a rock and/or ice core 10–30 times the mass of the Earth, and this core is likely soluble in the gas envelope above, and so primordial in composition. Since the core still exists, the outer envelope must have originally accreted onto a previously existing planetary core.<ref name="Stevenson 1982" /> Thermal contraction/evolution models support the presence of metallic hydrogen within the core in large abundances (greater than Saturn).<ref name="Pollack, et al. 1977" />
SaturnEdit
Saturn has an observed magnetic field generated within its metallic core.<ref name="Pollack, et al. 1977"/> Metallic hydrogen is present within the core (in lower abundances than Jupiter).<ref name="Pollack, et al. 1977" /> Saturn has a rock and or ice core 10–30 times the mass of the Earth, and this core is likely soluble in the gas envelope above, and therefore it is primordial in composition. Since the core still exists, the envelope must have originally accreted onto previously existing planetary cores.<ref name="Stevenson 1982" /> Thermal contraction/evolution models support the presence of metallic hydrogen within the core in large abundances (but still less than Jupiter).<ref name="Pollack, et al. 1977" />
Remnant planetary coresEdit
Missions to bodies in the asteroid belt will provide more insight to planetary core formation. It was previously understood that collisions in the solar system fully merged, but recent work on planetary bodies argues that remnants of collisions have their outer layers stripped, leaving behind a body that would eventually become a planetary core.<ref>Template:Cite journal</ref> The Psyche mission, titled “Journey to a Metal World,” is aiming to studying a body that could possibly be a remnant planetary core.<ref>Template:Cite book</ref>
ExtrasolarEdit
As the field of exoplanets grows as new techniques allow for the discovery of both diverse exoplanets, the cores of exoplanets are being modeled. These depend on initial compositions of the exoplanets, which is inferred using the absorption spectra of individual exoplanets in combination with the emission spectra of their star.
Chthonian planetsEdit
A chthonian planet results when a gas giant has its outer atmosphere stripped away by its parent star, likely due to the planet's inward migration. All that remains from the encounter is the original core.
Planets derived from stellar cores and diamond planetsEdit
Carbon planets, previously stars, are formed alongside the formation of a millisecond pulsar. The first such planet discovered was 18 times the density of water, and five times the size of Earth. Thus the planet cannot be gaseous, and must be composed of heavier elements that are also cosmically abundant like carbon and oxygen; making it likely crystalline like a diamond.<ref name="National Geographic Society 2011">Template:Cite journal</ref>
PSR J1719-1438 is a 5.7 millisecond pulsar found to have a companion with a mass similar to Jupiter but a density of 23 g/cm3, suggesting that the companion is an ultralow mass carbon white dwarf, likely the core of an ancient star.<ref name="Bailes, et al. 2011">Template:Cite journal</ref>
Hot ice planetsEdit
Exoplanets with moderate densities (more dense than Jovian planets, but less dense than terrestrial planets) suggests that such planets like GJ1214b and GJ436 are composed of primarily water. Internal pressures of such water-worlds would result in exotic phases of water forming on the surface and within their cores.<ref name="MessageToEagle.com 2012">{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>