Carbon isotopic signatures of super-deep diamonds mediated by iron redox chemistry

J. Liu¹,

¹Department of Geological Sciences, Jackson School of Geosciences, University of Texas at Austin, Austin, Texas 78712, USA

W. Wang²,

²Laboratory of Seismology and Physics of Earth’s Interior, School of Earth and Space Sciences, University of Science and Technology of China, Hefei, China

H. Yang³,

³Center for High Pressure Science and Technology Advanced Research (HPSTAR), Pudong, Shanghai 201203, China

Z. Wu^2,4,

²Laboratory of Seismology and Physics of Earth’s Interior, School of Earth and Space Sciences, University of Science and Technology of China, Hefei, China
⁴CAS Center for Excellence in Comparative Planetology, China

M.Y. Hu⁵,

⁵Advanced Photon Source, Argonne National Laboratory, Argonne, Illinois 60439, USA

J. Zhao⁵,

⁵Advanced Photon Source, Argonne National Laboratory, Argonne, Illinois 60439, USA

W. Bi^5,6,

⁵Advanced Photon Source, Argonne National Laboratory, Argonne, Illinois 60439, USA
⁶Department of Geology, University of Illinois at Urbana-Champaign, Urbana, Illinois 61801, USA

E.E. Alp⁵,

⁵Advanced Photon Source, Argonne National Laboratory, Argonne, Illinois 60439, USA

N. Dauphas⁷,

⁷Origins Laboratory, Department of the Geophysical Sciences and Enrico Fermi Institute, The University of Chicago, 5734 South Ellis Avenue, Chicago, Illinois 60637, USA

W. Liang⁸,

⁸Key Laboratory for High Temperature and High Pressure Study of the Earth’s Interior, Institute of Geochemistry, Chinese Academy of Sciences, Guiyang, Guizhou 550002, China

B. Chen⁹,

⁹Hawaii Institute of Geophysics and Planetology, University of Hawaii at Manoa, Honolulu, HI 96822, USA

J.-F. Lin¹

¹Department of Geological Sciences, Jackson School of Geosciences, University of Texas at Austin, Austin, Texas 78712, USA

Affiliations | Corresponding Author | Cite as | Funding information

Geochemical Perspectives Letters v10 | doi: 10.7185/geochemlet.1915
Received 28 May 2018 | Accepted 09 April 2019 | Published 24 May 2019

Published by the European Association of Geochemistry
under Creative Commons License CC BY-NC-ND 4.0

Keywords: carbon isotope, super-deep diamonds, Fe-C melt



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Abstract

Among redox sensitive elements, carbon is particularly important because it may have been a driver rather than a passive recorder of Earth’s redox evolution. The extent to which the isotopic composition of carbon records the redox processes that shaped the Earth is still debated. In particular, the highly reduced deep mantle may be metal-saturated, however, it is still unclear how the presence of metallic phases influences the carbon isotopic compositions of super-deep diamonds. Here we report ab initio results for the vibrational properties of carbon in carbonates, diamond, and Fe₃C under pressure and temperature conditions relevant to super-deep diamond formation. Previous work on this question neglected the effect of pressure on the equilibrium carbon isotopic fractionation between diamond and Fe₃C but our calculations show that this assumption overestimates the fractionation by a factor of ~1.3. Our calculated probability density functions for the carbon isotopic compositions of super-deep diamonds derived from metallic melt can readily explain the very light carbon isotopic compositions observed in some super-deep diamonds. Our results therefore support the view that metallic phases are present during the formation of super-deep diamonds in the mantle below ~250 km.

Figures and Tables

Figure 1 Partial phonon density of states (PDOS) of ⁵⁷Fe (a, b) and ¹²C (c, d) in FeCO₃ at high pressures. In (a) and (b), the open cycles are PDOS of Fe measured by NRIXS; the blue curves are calculated PDOS of Fe by DFT +U. The red curves in (c) and (d) are calculated PDOS of C. The lowest energy peak at 20-40 meV can be attributed to the acoustic phonons. According to previous high pressure Raman and infrared studies of FeCO₃ (Santillán and Williams, 2004; Lin et al., 2012), the other peaks can be assigned to librational mode (L), translational mode (T) and in-plane bending mode (v4), out of plane bending vibration (v2) and asymmetric stretch (v3) of CO₃^2- (marked as dashed vertical lines). The energies of v2 and v3 modes (marked as dotted vertical lines) at 60 GPa are linearly extrapolated from those measured up to 50 GPa for FeCO₃(Santillán and Williams, 2004). In the PDOS of Fe at 60 GPa (b), the splitting of v4 mode at approximately 100-120 meV has also been observed in a previous Raman study (Lin et al., 2012), which is explained as a result of the enhanced interaction between low-spin Fe²⁺ and neighbouring CO₃^2- units.

Figure 2 Comparison of the histogram for δ¹³C of super-deep diamonds (left axis) and the probability density functions (PDFs, right axis) of δ¹³C^Diaderived from metallic melt for different P-T conditions. The red, green and black solid curves are calculated PDFs by using Δ¹³C^{Dia-FeC melt} at 250 km, 660 km and 1500 km depths along a cold slab geotherm (Yang et al., 2017), respectively. The yellow dotted curve is calculated by using Δ¹³C^{Dia-FeC melt} at 250 km along the modern mantle geotherm (Yang et al., 2017), which may be similar to the Archean mantle geotherm (Santosh et al., 2010). The pink dashed curve is for diamonds forming from C-H-O fluids, which is calculated using the largest reported value of Δ¹³C^Dia-COH (-2.9 ‰) (Cartigny et al., 2014). The inset figure shows the negative tailings of these three PDFs. δ¹³C data of super-deep diamonds are from Cartigny et al. (2014).

Figure 1

Figure 2

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Introduction

Diamonds are prime recorders of the carbon isotopic compositions of the Earth because some of them are sourced deeply from the longest, isolated regions of Earth’s mantle (Cartigny et al., 2014

Cartigny, P., Palot, M., Thomassot, E., Harris, J.W. (2014) Diamond Formation: A Stable Isotope Perspective. Annual Review of Earth and Planetary Sciences 42, 699–732.

). The δ¹³C values (deviations in per mille of ¹³C/¹²C ratios relative to V-PDB) of natural diamonds show a broad range of variations from -41 ‰ to +3 ‰ with a mode at -5 ± 3 ‰ (Cartigny et al., 2014

Cartigny, P., Palot, M., Thomassot, E., Harris, J.W. (2014) Diamond Formation: A Stable Isotope Perspective. Annual Review of Earth and Planetary Sciences 42, 699–732.

). Of particular interests are very low δ¹³C values of -26 ‰ to -41 ‰ found in some eclogitic and super-deep diamonds (e.g., De Stefano et al., 2009

De Stefano, A., Kopylova, M.G., Cartigny, P., Afanasiev, V. (2009) Diamonds and eclogites of the Jericho kimberlite (Northern Canada). Contributions to Mineralogy and Petrology 158, 295–315.

; Smart et al., 2011

Smart, K.A., Chacko, T., Stachel, T., Muehlenbachs, K., Stern, R.A., Heaman, L.M. (2011) Diamond growth from oxidized carbon sources beneath the Northern Slave Craton, Canada: A δ¹³C–N study of eclogite-hosted diamonds from the Jericho kimberlite. Geochimica et Cosmochimica Acta 75, 6027–6047.

; Smith et al., 2016

Smith, E.M., Shirey, S.B., Nestola, F., Bullock, E.S., Wang, J.H., Richardson, S.H., Wang, W.Y. (2016) Large gem diamonds from metallic liquid in Earth’s deep mantle. Science 354, 1403–1405.

). These low δ¹³C values are most commonly found in eclogitic diamonds (e.g., Walter et al., 2011

Walter, M.J., Kohn, S.C., Araujo, D., Bulanova, G.P., Smith, C.B., Gaillou, E., Wang, J., Steele, A., Shirey, S.B. (2011) Deep Mantle Cycling of Oceanic Crust: Evidence from Diamonds and Their Mineral Inclusions. Science 334, 54–57.

), which presumably incorporated a recycled oceanic crust component. It is thus unlikely that these δ¹³C values were inherited from Earth’s primordial materials. Although eclogitic diamonds with lowest δ¹³C values may originate from organic matter at 2.0-2.7 Ga (δ¹³C -40 ‰ to -60 ‰) (Smart et al., 2011

), such organic matter unlikely survives at the depths (300-1000 km) where super-deep diamonds form (e.g., Anzolini et al., 2019

Anzolini, C. et al. (2019) Depth of diamond formation obtained from single periclase inclusions. Geology 47, 219–222.

). Isotopic fractionation associated with diamond precipitation from either CH₄ or CO₂-bearing fluids (Galimov, 1991

Galimov, E.M. (1991) Isotope fractionation related to kimberlite magmatism and diamond formation. Geochimica et Cosmochimica Acta 55, 1697–1708.

) is also an unlikely explanation for the most negative δ¹³C values measured in these diamonds. The reasons are that: (1) the equilibrium fractionation between diamond and CH₄ at mantle temperatures (~+1 ‰) is too low to drive the residual fluid to very negative δ¹³C values by Rayleigh distillation; (2) the fractionation between diamond and CO₂ of ~-3 ‰ at mantle temperatures could only produce diamonds whose δ¹³C values are ~-8 ‰ or higher. Overall, the question of how some super-deep diamonds acquired highly negative δ¹³C values is still open.

Through plate tectonics, relatively oxidised iron and carbon species at the Earth’s surface are transported to the deep mantle by subducted slabs, where Fe²⁺ can disproportionate into Fe³⁺ and metallic Fe (Equation 1) below ~250 km due to stabilisation of Fe³⁺ in garnet, pyroxene and bridgmanite (Frost et al., 2004

Frost, D.J., Liebske, C., Langenhorst, F., McCammon, C.A., Tronnes, R.G., Rubie, D.C. (2004) Experimental evidence for the existence of iron-rich metal in the Earth’s lower mantle. Nature 428, 409–412.

; Rohrbach et al., 2007

Rohrbach, A., Ballhaus, C., Golla–Schindler, U., Ulmer, P., Kamenetsky, V.S., Kuzmin, D.V. (2007) Metal saturation in the upper mantle. Nature 449, 456–458.

Eq. 1

3FeO = Fe + Fe₂O₃

The resulting metallic Fe would react with carbonates to form either diamond (Equation 2) or iron carbide (Equation 3), depending on the local Fe:C ratio and thus redox state (Palyanov et al., 2013

Palyanov, Y.N., Bataleva, Y.V., Sokol, A.G., Borzdov, Y.M., Kupriyanov, I.N., Reutsky, V.N., Sobolev, N.V. (2013) Mantle-slab interaction and redox mechanism of diamond formation. Proceedings of the National Academy of Sciences of the United States of America 110, 20408–20413.

Eq. 2

FeCO₃ + 2Fe = 3FeO + C

Eq. 3

FeCO₃ + 5Fe = 3FeO + Fe₃C

Fe₃C can also serve as a reduced C source to form diamonds through the following redox reaction (Bataleva et al., 2016

Bataleva, Y.V., Palyanov, Y.N., Borzdov, Y.M., Bayukov, O.A., Sobolev, N.V. (2016) Conditions for diamond and graphite formation from iron carbide at the P-T parameters of lithospheric mantle. Russian Geology and Geophysics 57, 176–189.

Eq. 4

Fe₃C + 3Fe₂O₃ = 9FeO + C

Moreover, Fe-C alloys/mixtures may melt under the pressure and temperature (P-T) conditions of the mantle because of their relatively low melting temperatures, especially in the presence of Ni, as compared to other mantle minerals (e.g., Rohrbach et al., 2014

Rohrbach, A., Ghosh, S., Schmidt, M.W., Wijbrans, C.H., Klemme, S. (2014) The stability of Fe–Ni carbides in the Earth’s mantle: Evidence for a low Fe–Ni–C melt fraction in the deep mantle. Earth and Planetary Science Letters 388, 211–221.

; Liu et al., 2016

Liu, J., Li, J., Hrubiak, R., Smith, J.S. (2016) Origins of ultralow velocity zones through slab-derived metallic melt. Proceedings of the National Academy of Sciences 113, 5547–5551.

). The resultant Fe-C melt can form diamonds through the reaction mediated by iron redox chemistry:

Eq. 5

Fe-C melt + Fe₂O₃ = 3FeO + C

The presence of S or other light elements can significantly lower C solubility in metallic melt and therefore promote diamond formation (Bataleva et al., 2015

Bataleva, Y.V., Palyanov, Y.N., Borzdov, Y.M., Bayukov, O.A., Sobolev, N.V. (2015) Interaction of iron carbide and sulfur under P–T conditions of the lithospheric mantle. Doklady Earth Sciences 463, 707–711.

). For example, Fe-Ni-S-C inclusions have been found in super-deep diamonds (e.g., Kaminsky and Wirth, 2011

Kaminsky, F.V., Wirth, R. (2011) Iron Carbide Inclusions in Lower-Mantle Diamond from Juina, Brazil. Canadian Mineralogist 49, 555–572.

; Smith et al., 2016

Smith, E.M., Shirey, S.B., Nestola, F., Bullock, E.S., Wang, J.H., Richardson, S.H., Wang, W.Y. (2016) Large gem diamonds from metallic liquid in Earth’s deep mantle. Science 354, 1403–1405.

). Finding such metallic inclusions requires careful examination as these inclusions are small in size (µm to nm scale) and can be mistaken for graphite (Kaminsky and Wirth, 2011

Kaminsky, F.V., Wirth, R. (2011) Iron Carbide Inclusions in Lower-Mantle Diamond from Juina, Brazil. Canadian Mineralogist 49, 555–572.

; Smith et al., 2016

Smith, E.M., Shirey, S.B., Nestola, F., Bullock, E.S., Wang, J.H., Richardson, S.H., Wang, W.Y. (2016) Large gem diamonds from metallic liquid in Earth’s deep mantle. Science 354, 1403–1405.

). The presence of metallic inclusions supports the view that C-bearing metallic melt could serve as a carbon source for some super-deep diamonds below ~250 km.

Horita and Polyakov (2015)

Horita, J., Polyakov, V.B. (2015) Carbon-bearing iron phases and the carbon isotope composition of the deep Earth. Proceedings of the National Academy of Sciences 112, 31–36.

have attempted to address the aforementioned question through calculations of the reduced partition function ratio (β-factor) of C in Fe₃C using the heat capacity and the iron phonon density of states (PDOS) at 1 bar. They combined this β-factor with previously published β-factors of diamond and carbonates to calculate the carbon equilibrium isotopic fractionation Δ¹³C between these phases,

Eq. 6

Δ¹³C^B-A = 1000(lnβ_B - lnβ_A)

where A and B are two phases in isotopic equilibrium. An important assumption that Horita and Polyakov (2015)

Horita, J., Polyakov, V.B. (2015) Carbon-bearing iron phases and the carbon isotope composition of the deep Earth. Proceedings of the National Academy of Sciences 112, 31–36.

made is that pressure has no effect on this fractionation. However, super-deep diamonds form under high P-T conditions in the mantle below 250 km depth, and applied pressure has undoubtedly been shown to stiffen lattice bonds and induce structural and electronic transitions, which in turn can affect β-factors of C in host phases (e.g., Lin et al., 2004

Lin, J.-F., Struzhkin, V.V., Mao, H., Hemley, R.J., Chow, P., Hu, M.Y., Li, J. (2004) Magnetic transition in compressed Fe₃C from x-ray emission spectroscopy. Physical Review B 70, 212405.

, 2012

Lin, J.-F., Liu, J., Jacobs, C., Prakapenka, V.B. (2012) Vibrational and elastic properties of ferromagnesite across the electronic spin-pairing transition of iron. American Mineralogist 97, 583–591.

). In order to constrain reliably the extent of C isotopic fractionation during super-deep diamond formation, we used DFT augmented by a Hubbard U correction method (Giannozzi et al., 2009

Giannozzi, P., Baroni, S., Bonini, N., Calandra, M. , Car, R., et al. (2009) QUANTUM ESPRESSO: a modular and open-source software project for quantum simulations of materials. Journal of Physics: Condensed Matter 21, 395502.

) to calculate the β-factors of C in MgCO₃, FeCO₃, Fe₃C and diamond (Tables S-1, S-2) at the P-T conditions of subducted slabs in the mantle. We also measured the PDOS of Fe²⁺ in FeCO₃ by nuclear resonant inelastic X-ray scattering (NRIXS) spectroscopy (Dauphas et al., 2018

Dauphas, N., Hu, M.Y., Baker, E.M., Hu, J., Tissot, F.L.H., Alp, E.E., Roskosz, M., Zhao, J., Bi, W., Liu, J., J.-F., Niea, N.X., Heard, A. (2018) SciPhon: a data analysis software for nuclear resonant inelastic X-ray scattering with applications to Fe, Kr, Sn, Eu and Dy. Journal of Synchrotron Radiation 25, 1581–1599.

) to evaluate the accuracy of the theoretical calculations.

**Figure 1** Partial phonon density of states (PDOS) of ⁵⁷Fe **(a, b)** and ¹²C **(c, d)** in FeCO₃ at high pressures. In **(a)** and **(b)**, the open cycles are PDOS of Fe measured by NRIXS; the blue curves are calculated PDOS of Fe by DFT +U. The red curves in **(c)** and **(d)** are calculated PDOS of C. The lowest energy peak at 20-40 meV can be attributed to the acoustic phonons. According to previous high pressure Raman and infrared studies of FeCO₃ (Santillán and Williams, 2004
Santillán, J., Williams, Q. (2004) A high-pressure infrared and X-ray study of FeCO₃ and MnCO₃: comparison with CaMg(CO₃)₂-dolomite. *Physics of the Earth and Planetary Interiors* 143–144, 291–304.
; Lin *et al.*, 2012
Lin, J.-F., Liu, J., Jacobs, C., Prakapenka, V.B. (2012) Vibrational and elastic properties of ferromagnesite across the electronic spin-pairing transition of iron. *American Mineralogist* 97, 583–591.
), the other peaks can be assigned to librational mode (L), translational mode (T) and in-plane bending mode (v4), out of plane bending vibration (v2) and asymmetric stretch (v3) of CO₃^2- (marked as dashed vertical lines). The energies of v2 and v3 modes (marked as dotted vertical lines) at 60 GPa are linearly extrapolated from those measured up to 50 GPa for FeCO₃(Santillán and Williams, 2004
Santillán, J., Williams, Q. (2004) A high-pressure infrared and X-ray study of FeCO₃ and MnCO₃: comparison with CaMg(CO₃)₂-dolomite. *Physics of the Earth and Planetary Interiors* 143–144, 291–304.
). In the PDOS of Fe at 60 GPa **(b)**, the splitting of v4 mode at approximately 100-120 meV has also been observed in a previous Raman study (Lin *et al.*, 2012
Lin, J.-F., Liu, J., Jacobs, C., Prakapenka, V.B. (2012) Vibrational and elastic properties of ferromagnesite across the electronic spin-pairing transition of iron. *American Mineralogist* 97, 583–591.
), which is explained as a result of the enhanced interaction between low-spin Fe²⁺ and neighbouring CO₃^2- units.

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PDOS of Fe and C in Minerals Relevant to Diamond Formation

The DFT + U calculation was verified by comparing the theoretical PDOS of Fe²⁺in FeCO₃ with the one measured by NRIXS (Fig .1). The PDOS results in theory and experiment match well with each other, which could also support the validity of the calculated β-factors of C in carbonates, diamond and nonmagnetic Fe₃C (Fig. S-1). Synchrotron Mössbauer spectra (Fig. S-2) and optical images (Fig. S-3) show that the spin transition of Fe²⁺in FeCO₃ occurs between 44-46 GPa at 300 K. Across the spin transition, the unit cell volume collapses by 9.4 %, the Fe-O bond length is shortened by 4.8 % (Fig. S-4). Meanwhile, the spin transition of iron results in ~5 % decrease of the β-factor of C in LS FeCO₃ compared to its HS state (Fig. S-5) as the C-O bound length is lengthened by 2.1 % (Fig. S-4). The magnetic state of Fe₃C changes from ferromagnetic at ambient condition to paramagnetic and finally nonmagnetic at pressures higher than ~22-60 GPa (Lin et al., 2004

Lin, J.-F., Struzhkin, V.V., Mao, H., Hemley, R.J., Chow, P., Hu, M.Y., Li, J. (2004) Magnetic transition in compressed Fe₃C from x-ray emission spectroscopy. Physical Review B 70, 212405.

; Gao et al., 2008

Gao, L., Chen, B., Wang, J., Alp, E.E., Zhao, J., Lerche, M., Sturhahn, W., Scott, H.P., Huang, F., Ding, Y., Sinogeikin, S.V., Lundstrom, C.C., Bass, J.D., Li, J. (2008) Pressure-induced magnetic transition and sound velocities of Fe₃C: Implications for carbon in the Earth’s inner core. Geophysical Research Letters 35, L17306.

). Therefore, nonmagnetic Fe₃C is the relevant phase for most mantle depths. Similar to previous theoretical calculations (Horita and Polyakov, 2015

Horita, J., Polyakov, V.B. (2015) Carbon-bearing iron phases and the carbon isotope composition of the deep Earth. Proceedings of the National Academy of Sciences 112, 31–36.

) and C isotopic measurements on natural diamonds and iron carbide inclusions (Mikhail et al., 2014

Mikhail, S., Guillermier, C., Franchi, I.A., Beard, A.D., Crispin, K., Verchovsky, A.B., Jones, A.P., Milledge, H.J. (2014) Empirical evidence for the fractionation of carbon isotopes between diamond and iron carbide from the Earth’s mantle. Geochemistry, Geophysics, Geosystems 15, 855–866.

), the magnitude of ΔC^Dia-Fe₃C is larger than other inter-mineral fractionations involving diamond, such as ΔC^{Dia-Carbonates} (Fig. S-6). Our calculated ΔC^Dia-Fe₃C values along the representative P-T conditions of modern mantle and cold slab (Fig. S-6) are as much as 27 % lower than the 1 bar value of ΔC^Dia-Fe₃C reported by Horita and Polyakov (2015)

Horita, J., Polyakov, V.B. (2015) Carbon-bearing iron phases and the carbon isotope composition of the deep Earth. Proceedings of the National Academy of Sciences 112, 31–36.

. Therefore the 1 bar data would overestimate the C isotopic fractionation during diamond formation from a Fe₃C source under representative mantle P-T conditions.

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Carbon Isotopic Fractionation in Diamonds through Redox Reactions

As discussed by Horita and Polyakov (2015)

Horita, J., Polyakov, V.B. (2015) Carbon-bearing iron phases and the carbon isotope composition of the deep Earth. Proceedings of the National Academy of Sciences 112, 31–36.

, the most significant reaction that can impart C isotopic fractionation to diamonds is one involving the oxidation of C alloyed with metallic melt to release C to form diamonds (Equation 5). To assess how redox reactions involving Fe-C melt below ~250 km can influence the δ¹³C values of super-deep diamonds, we modelled the isotopic fractionation of C between diamond and Fe-C melt. Our calculations accounting for various P-T and compositional factors allow us to test whether this diamond formation pathway can account for their δ¹³C values.

The C isotopic fractionation can be modelled by using a Rayleigh distillation if the diamonds produced do not back-react with the C source, which is reasonable if the Fe-C source is a melt and the reaction product is a solid characterised by a low self-diffusivity (Koga et al., 2005

Koga, K.T., Walter, M.J., Nakamura, E., Kobayashi, K. (2005) Carbon self-diffusion in a natural diamond. Physical Review B 72, 024108.

). As it is challenging to calculate the β-factor of C in Fe-C melt directly, Δ¹³C^{Dia-FeC melt} is calculated by the sum of Δ¹³C^Dia-Fe₃C (Fig. S-6) and the equilibrium fractionation Δ¹³C^Fe₃C-^FeC^melt= -5.6 × 10⁶/T² anchored to the experimentally determined value of ~-2 ‰ at 6.3 GPa and 1673 K (Reutsky et al., 2015

Reutsky, V.N., Borzdov, Y.M., Palyanov, Y.N. (2015) Carbon isotope fractionation during high pressure and high temperature crystallization of Fe–C melt. Chemical Geology 406, 18–24.

). By using this calculated Δ¹³C^{Dia-FeC melt}, δ¹³C values of diamonds forming from metallic melt can be calculated using a Rayleigh distillation model. Relative to the Fe-C melt source, the diamonds are enriched in the heavy isotope of C. Removal of isotopically heavy diamonds would have driven the Fe-C melt reservoir towards lower δ¹³C values and diamonds formed from this low δ¹³C reservoir progressively acquired more negative δ¹³C values.

**Figure 2** Comparison of the histogram for δ¹³C of super-deep diamonds (left axis) and the probability density functions (PDFs, right axis) of δ¹³C^Diaderived from metallic melt for different *P-T* conditions. The red, green and black solid curves are calculated PDFs by using Δ¹³C^{Dia-FeC melt} at 250 km, 660 km and 1500 km depths along a cold slab geotherm (Yang *et al.*, 2017
Yang, D., Wang, W., Wu, Z. (2017) Elasticity of superhydrous phase B at the mantle temperatures and pressures: Implications for 800 km discontinuity and water flow into the lower mantle. *Journal of Geophysical Research: Solid Earth* 122, 5026–5037.
), respectively. The yellow dotted curve is calculated by using Δ¹³C^{Dia-FeC melt} at 250 km along the modern mantle geotherm (Yang *et al.*, 2017
Yang, D., Wang, W., Wu, Z. (2017) Elasticity of superhydrous phase B at the mantle temperatures and pressures: Implications for 800 km discontinuity and water flow into the lower mantle. *Journal of Geophysical Research: Solid Earth* 122, 5026–5037.
), which may be similar to the Archean mantle geotherm (Santosh *et al.*, 2010
Santosh, M., Maruyama, S., Komiya, T., Yamamoto, S. (2010) Orogens in the evolving Earth: from surface continents to ‘lost continents’ at the core–mantle boundary. *Geological Society, London, Special Publications* 338, 77–116.
). The pink dashed curve is for diamonds forming from C-H-O fluids, which is calculated using the largest reported value of Δ¹³C^Dia-COH (-2.9 ‰) (Cartigny *et al.*, 2014
Cartigny, P., Palot, M., Thomassot, E., Harris, J.W. (2014) Diamond Formation: A Stable Isotope Perspective. *Annual Review of Earth and Planetary Sciences* 42, 699–732.
). The inset figure shows the negative tailings of these three PDFs. δ¹³C data of super-deep diamonds are from Cartigny *et al.* (2014)
Cartigny, P., Palot, M., Thomassot, E., Harris, J.W. (2014) Diamond Formation: A Stable Isotope Perspective. *Annual Review of Earth and Planetary Sciences* 42, 699–732.
.

The probability density function (PDF) of δ¹³C^Dia values of diamond formed from metallic melt, which we note as g(δ¹³C^Dia), is simply given as below (see detailed derivation in Supplementary Information),

Eq. 7

g(δ¹³C^Dia) = 1/Δ¹³C^Dia-Sourceexp[(δ¹³C^Dia- δ¹³C₀^Source)/ Δ¹³C^Dia-Source -1]

The PDFs for Δ¹³C^Dia-Fe₃C at representative upper mantle, transition zone, and lower mantle depths are shown in Fig. 2. For each PDF, δ¹³C₀^Source is set to locate the maximum probability of δ¹³C^Dia at -5 ‰, which is the mode of δ¹³C of worldwide diamonds (Cartigny et al., 2014

Cartigny, P., Palot, M., Thomassot, E., Harris, J.W. (2014) Diamond Formation: A Stable Isotope Perspective. Annual Review of Earth and Planetary Sciences 42, 699–732.

). Because of the decrease of Δ¹³C^{Dia-FeC melt} with increasing depth and temperature, the extent of the negative tail of each PDF decreases with depth where diamonds form (Fig. 2). For example, the cumulative probability of δ¹³C^Dia values lower than -26 ‰ is ~0.17 at 250 km, and it decreases to 0.10 and 0.05 at 660 and 1500 km depths, respectively (Fig. S-7). This shows that super-deep diamonds with very light C isotope could have formed from C-bearing metallic melt in the reduced part (>250 km) of the upper mantle.

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Conclusion

By using the β-factors of carbon in relevant minerals/melt, the carbon isotopic fractionations between carbon-bearing phases possibly involved in super-deep diamond formation are calculated. The corresponding PDFs for δ¹³C of super-deep diamonds from different carbon sources are derived. Based on the comparison between the histogram for δ¹³C of super-deep diamonds and the derived PDFs, super-deep diamonds could crystallise from C-saturated metallic melt, thus supporting the existence of a deep mantle saturated in metallic iron.

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Acknowledgements

W.Z. Wang and Z.Q. Wu acknowledge the Strategic Priority Research Program of the Chinese Academy of Sciences (XDB18000000), the Natural Science Foundation of China (41721002). J.F.L. and N.D. acknowledge support from CSEDI of the NSF Geophysics Program (EAR-1502594). NRIXS experiments used resources of the Advanced Photon Source, a U.S. Department of Energy (DOE) Office of Science User Facility operated for the DOE Office of Science by Argonne National Laboratory under Contract No. DE-AC02-06CH11357. W. Liang acknowledges the National Science Foundation for Young Scientists of China (41802044). W.L. Bi acknowledges COMPRES, the Consortium for Materials Properties Research in Earth Sciences under NSF Cooperative Agreement EAR 1606856. B. Chen acknowledges support from NSF grants EAR-1555388 and EAR-1565708.

Editor: Wendy Mao

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Author Contributions

J.C. Liu and W.Z. Wang contributed equally to this work. J.F. Lin, J.C. Liu and W.Z. Wang designed this project. J.C. Liu, H. Yang, N. Dauphas, M.Y. Hu, J.Y. Zhao, W.L, Bi, E.E. Alp, W. Liang and B. Chen performed the experiments and data analysis. W.Z. Wang and Z.Q. Wu performed the calculations. J.C. Liu, W.Z. Wang, N. Dauphas and J.F. Lin wrote the paper.

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References

Anzolini, C. et al. (2019) Depth of diamond formation obtained from single periclase inclusions. Geology 47, 219–222.

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Although eclogitic diamonds with lowest δ¹³C values may originate from organic matter at 2.0-2.7 Ga (δ¹³C -40 ‰ to -60 ‰) (Smart et al., 2011), such organic matter unlikely survives at the depths (300-1000 km) where super-deep diamonds form (e.g., Anzolini et al., 2019).
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The presence of S or other light elements can significantly lower C solubility in metallic melt and therefore promote diamond formation (Bataleva et al., 2015).
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Fe₃C can also serve as a reduced C source to form diamonds through the following redox reaction (Bataleva et al., 2016): Fe₃C + 3Fe₂O₃ = 9FeO + C
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Cartigny, P., Palot, M., Thomassot, E., Harris, J.W. (2014) Diamond Formation: A Stable Isotope Perspective. Annual Review of Earth and Planetary Sciences 42, 699–732.

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Diamonds are prime recorders of the carbon isotopic compositions of the Earth because some of them are sourced deeply from the longest, isolated regions of Earth’s mantle (Cartigny et al., 2014).
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The δ¹³C values (deviations in per mille of ¹³C/¹²C ratios relative to V-PDB) of natural diamonds show a broad range of variations from -41 ‰ to +3 ‰ with a mode at -5 ± 3 ‰ (Cartigny et al., 2014).
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Figure 2 [...] The pink dashed curve is for diamonds forming from C-H-O fluids, which is calculated using the largest reported value of Δ¹³C^Dia-COH (-2.9 ‰) (Cartigny et al., 2014).
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Figure 2 [...] δ¹³C data of super-deep diamonds are from Cartigny et al. (2014).
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For each PDF, δ¹³C₀^Source is set to locate the maximum probability of δ¹³C^Dia at -5 ‰, which is the mode of δ¹³C of worldwide diamonds (Cartigny et al., 2014).
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We also measured the PDOS of Fe²⁺ in FeCO₃ by nuclear resonant inelastic X-ray scattering (NRIXS) spectroscopy (Dauphas et al., 2018) to evaluate the accuracy of the theoretical calculations.
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De Stefano, A., Kopylova, M.G., Cartigny, P., Afanasiev, V. (2009) Diamonds and eclogites of the Jericho kimberlite (Northern Canada). Contributions to Mineralogy and Petrology 158, 295–315.

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Through plate tectonics, relatively oxidised iron and carbon species at the Earth’s surface are transported to the deep mantle by subducted slabs, where Fe²⁺ can disproportionate into Fe³⁺ and metallic Fe (Equation 1) below ~250 km due to stabilisation of Fe³⁺ in garnet, pyroxene and bridgmanite (Frost et al., 2004; Rohrbach et al., 2007): 3FeO = Fe + Fe₂O₃
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Galimov, E.M. (1991) Isotope fractionation related to kimberlite magmatism and diamond formation. Geochimica et Cosmochimica Acta 55, 1697–1708.

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Isotopic fractionation associated with diamond precipitation from either CH₄ or CO₂-bearing fluids (Galimov, 1991) is also an unlikely explanation for the most negative δ¹³C values measured in these diamonds.
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The magnetic state of Fe₃C changes from ferromagnetic at ambient condition to paramagnetic and finally nonmagnetic at pressures higher than ~22-60 GPa (Lin et al., 2004; Gao et al., 2008).
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In order to constrain reliably the extent of C isotopic fractionation during super-deep diamond formation, we used DFT augmented by a Hubbard U correction method (Giannozzi et al., 2009) to calculate the β-factors of C in MgCO₃, FeCO₃, Fe₃C and diamond (Tables S-1, S-2) at the P-T conditions of subducted slabs in the mantle.
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Horita, J., Polyakov, V.B. (2015) Carbon-bearing iron phases and the carbon isotope composition of the deep Earth. Proceedings of the National Academy of Sciences 112, 31–36.

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Horita and Polyakov (2015) have attempted to address the aforementioned question through calculations of the reduced partition function ratio (β-factor) of C in Fe₃C using the heat capacity and the iron phonon density of states (PDOS) at 1 bar.
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An important assumption that Horita and Polyakov (2015) made is that pressure has no effect on this fractionation.
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Similar to previous theoretical calculations (Horita and Polyakov, 2015) and C isotopic measurements on natural diamonds and iron carbide inclusions (Mikhail et al., 2014), the magnitude of ΔC^Dia-Fe₃C is larger than other inter-mineral fractionations involving diamond, such as ΔC^{Dia-Carbonates} (Fig. S-6).
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Our calculated ΔC^Dia-Fe₃C values along the representative P-T conditions of modern mantle and cold slab (Fig. S-6) are as much as 27 % lower than the 1 bar value of ΔC^Dia-Fe₃C reported by Horita and Polyakov (2015).
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As discussed by Horita and Polyakov (2015), the most significant reaction that can impart C isotopic fractionation to diamonds is one involving the oxidation of C alloyed with metallic melt to release C to form diamonds (Equation 5).
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Kaminsky, F.V., Wirth, R. (2011) Iron Carbide Inclusions in Lower-Mantle Diamond from Juina, Brazil. Canadian Mineralogist 49, 555–572.

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For example, Fe-Ni-S-C inclusions have been found in super-deep diamonds (e.g., Kaminsky and Wirth, 2011; Smith et al., 2016).
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Finding such metallic inclusions requires careful examination as these inclusions are small in size (µm to nm scale) and can be mistaken for graphite (Kaminsky and Wirth, 2011; Smith et al., 2016).
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Koga, K.T., Walter, M.J., Nakamura, E., Kobayashi, K. (2005) Carbon self-diffusion in a natural diamond. Physical Review B 72, 024108.

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The C isotopic fractionation can be modelled by using a Rayleigh distillation if the diamonds produced do not back-react with the C source, which is reasonable if the Fe-C source is a melt and the reaction product is a solid characterised by a low self-diffusivity (Koga et al., 2005).
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Lin, J.-F., Struzhkin, V.V., Mao, H., Hemley, R.J., Chow, P., Hu, M.Y., Li, J. (2004) Magnetic transition in compressed Fe₃C from x-ray emission spectroscopy. Physical Review B 70, 212405.

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However, super-deep diamonds form under high P-T conditions in the mantle below 250 km depth, and applied pressure has undoubtedly been shown to stiffen lattice bonds and induce structural and electronic transitions, which in turn can affect β-factors of C in host phases (e.g., Lin et al., 2004, 2012).
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Figure 1 [...] According to previous high pressure Raman and infrared studies of FeCO₃ (Santillán and Williams, 2004; Lin et al., 2012), the other peaks can be assigned to librational mode (L), translational mode (T) and in-plane bending mode (v4), out of plane bending vibration (v2) and asymmetric stretch (v3) of CO₃^2- (marked as dashed vertical lines).
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Figure 1 [...] In the PDOS of Fe at 60 GPa (b), the splitting of v4 mode at approximately 100-120 meV has also been observed in a previous Raman study (Lin et al., 2012), which is explained as a result of the enhanced interaction between low-spin Fe²⁺ and neighbouring CO₃^2- units.
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Liu, J., Li, J., Hrubiak, R., Smith, J.S. (2016) Origins of ultralow velocity zones through slab-derived metallic melt. Proceedings of the National Academy of Sciences 113, 5547–5551.

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Moreover, Fe-C alloys/mixtures may melt under the pressure and temperature (P-T) conditions of the mantle because of their relatively low melting temperatures, especially in the presence of Ni, as compared to other mantle minerals (e.g., Rohrbach et al., 2014; Liu et al., 2016).
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Similar to previous theoretical calculations (Horita and Polyakov, 2015) and C isotopic measurements on natural diamonds and iron carbide inclusions (Mikhail et al., 2014), the magnitude of ΔC^Dia-Fe₃C is larger than other inter-mineral fractionations involving diamond, such as ΔC^{Dia-Carbonates} (Fig. S-6).
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The resulting metallic Fe would react with carbonates to form either diamond (Equation 2) or iron carbide (Equation 3), depending on the local Fe:C ratio and thus redox state (Palyanov et al., 2013): FeCO₃ + 2Fe = 3FeO + C
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Reutsky, V.N., Borzdov, Y.M., Palyanov, Y.N. (2015) Carbon isotope fractionation during high pressure and high temperature crystallization of Fe–C melt. Chemical Geology 406, 18–24.

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As it is challenging to calculate the β-factor of C in Fe-C melt directly, Δ¹³C^Dia-FeC melt is calculated by the sum of Δ¹³C^Dia-Fe₃C (Fig. S-6) and the equilibrium fractionation Δ¹³C^{Fe₃C-FeC melt} = -5.6 × 10⁶/T² anchored to the experimentally determined value of ~-2 ‰ at 6.3 GPa and 1673 K (Reutsky et al., 2015).
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Rohrbach, A., Ballhaus, C., Golla–Schindler, U., Ulmer, P., Kamenetsky, V.S., Kuzmin, D.V. (2007) Metal saturation in the upper mantle. Nature 449, 456–458.

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Santillán, J., Williams, Q. (2004) A high-pressure infrared and X-ray study of FeCO₃ and MnCO₃: comparison with CaMg(CO₃)₂-dolomite. Physics of the Earth and Planetary Interiors 143–144, 291–304.

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Figure 1 [...] According to previous high pressure Raman and infrared studies of FeCO₃ (Santillán and Williams, 2004; Lin et al., 2012), the other peaks can be assigned to librational mode (L), translational mode (T) and in-plane bending mode (v4), out of plane bending vibration (v2) and asymmetric stretch (v3) of CO₃^2- (marked as dashed vertical lines).
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Figure 1 [...] The energies of v2 and v3 modes (marked as dotted vertical lines) at 60 GPa are linearly extrapolated from those measured up to 50 GPa for FeCO₃ (Santillán and Williams, 2004).
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Santosh, M., Maruyama, S., Komiya, T., Yamamoto, S. (2010) Orogens in the evolving Earth: from surface continents to ‘lost continents’ at the core–mantle boundary. Geological Society, London, Special Publications 338, 77–116.

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Figure 2 [...] The yellow dotted curve is calculated by using Δ¹³C^{Dia-FeC melt} at 250 km along the modern mantle geotherm (Yang et al., 2017), which may be similar to the Archean mantle geotherm (Santosh et al., 2010).
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Of particular interests are very low δ¹³C values of -26 ‰ to -41 ‰ found in some eclogitic and super-deep diamonds (e.g., De Stefano et al., 2009; Smart et al., 2011; Smith et al., 2016).
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Although eclogitic diamonds with lowest δ¹³C values may originate from organic matter at 2.0-2.7 Ga (δ¹³C -40 ‰ to -60 ‰) (Smart et al., 2011), such organic matter unlikely survives at the depths (300-1000 km) where super-deep diamonds form (e.g., Anzolini et al., 2019).
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Smith, E.M., Shirey, S.B., Nestola, F., Bullock, E.S., Wang, J.H., Richardson, S.H., Wang, W.Y. (2016) Large gem diamonds from metallic liquid in Earth’s deep mantle. Science 354, 1403–1405.

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Of particular interests are very low δ¹³C values of -26 ‰ to -41 ‰ found in some eclogitic and super-deep diamonds (e.g., De Stefano et al., 2009; Smart et al., 2011; Smith et al., 2016).
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For example, Fe-Ni-S-C inclusions have been found in super-deep diamonds (e.g., Kaminsky and Wirth, 2011; Smith et al., 2016).
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Finding such metallic inclusions requires careful examination as these inclusions are small in size (µm to nm scale) and can be mistaken for graphite (Kaminsky and Wirth, 2011; Smith et al., 2016).
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These low δ¹³C values are most commonly found in eclogitic diamonds (e.g., Walter et al., 2011), which presumably incorporated a recycled oceanic crust component.
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Yang, D., Wang, W., Wu, Z. (2017) Elasticity of superhydrous phase B at the mantle temperatures and pressures: Implications for 800 km discontinuity and water flow into the lower mantle. Journal of Geophysical Research: Solid Earth 122, 5026–5037.

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Figure 2 [...] The red, green and black solid curves are calculated PDFs by using Δ¹³C^{Dia-FeC melt} at 250 km, 660 km and 1500 km depths along a cold slab geotherm (Yang et al., 2017), respectively.
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Figure 2 [...] The yellow dotted curve is calculated by using Δ¹³C^{Dia-FeC melt} at 250 km along the modern mantle geotherm (Yang et al., 2017), which may be similar to the Archean mantle geotherm (Santosh et al., 2010).
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