Jannes König scite author profile

The synthesis of a novel type of carbonate, namely of the inorganic pyrocarbonate salt Sr[C2O5], which contains isolated [C2O5]2–-groups, significantly extends the crystal chemistry of inorganic carbonates beyond the established sp 2- and sp 3-carbonates. We synthesized Sr[C2O5] in a laser-heated diamond anvil cell by reacting Sr[CO3] with CO2. By single crystal synchrotron diffraction, Raman spectroscopy, and density functional theory (DFT) calculations, we show that it is a pyrocarbonate salt. Sr[C2O5] is the first member of a novel family of inorganic carbonates. We predict, based on DFT calculations, that further inorganic pyrocarbonates can be obtained and that these will be relevant to geoscience and may provide a better understanding of reactions converting CO2 into useful inorganic compounds.

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Sr₃[CO₄]O Antiperovskite with Tetrahedrally Coordinated sp³-Hybridized Carbon and OSr₆ Octahedra

Spahr

König

Bayarjargal

et al. 2021

Inorg. Chem.

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We have synthesized the orthocarbonate Sr 3 [CO 4 ]O in a laserheated diamond anvil cell at 20 and 30 GPa by heating to ≈3000 (300) K. Afterward, we recovered the orthocarbonate with [CO 4 ] 4− groups at ambient conditions. Single-crystal diffraction shows the presence of [CO 4 ] 4− groups, i.e., sp 3hybridized carbon tetrahedrally coordinated by covalently bound oxygen atoms. The [CO 4 ] 4− tetrahedra are located in a cage formed by corner-sharing OSr 6 octahedra, i.e., octahedra with oxygen as a central ion, forming an antiperovskite-type structure. At high pressures, the octahedra are nearly ideal and slightly rotated. The highpressure phase is tetragonal (I4/mcm). Upon pressure release, there is a phase transition with a symmetry lowering to an orthorhombic phase (Pnma), where the octahedra tilt and deform slightly.

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Synthesis and Structure of Pb[C₂O₅]: An Inorganic Pyrocarbonate Salt

et al. 2022

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We have synthesized Pb[C2O5], an inorganic pyrocarbonate salt, in a laser-heated diamond anvil cell (LH-DAC) at 30 GPa by heating a Pb[CO3] + CO2 mixture to ≈2000(200) K. Inorganic pyrocarbonates contain isolated [C2O5]2– groups without functional groups attached. The [C2O5]2– groups consist of two oxygen-sharing [CO3]3– groups. Pb[C2O5] was characterized by synchrotron-based single-crystal structure refinement, Raman spectroscopy, and density functional theory calculations. Pb[C2O5] is isostructural to Sr[C2O5] and crystallizes in the monoclinic space group P21/c with Z = 4. The synthesis of Pb[C2O5] demonstrates that, just like in other carbonates, cation substitution is possible and that therefore inorganic pyrocarbonates are a novel family of carbonates, in addition to the established sp2 and sp3 carbonates.

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Novel Calcium sp³ Carbonate CaC₂O₅-I4̅2d May Be a Carbon Host in Earth’s Lower Mantle

König

Spahr

Bayarjargal

et al. 2022

ACS Earth Space Chem.

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CaC2O5-I4̅2d was obtained by reacting CO2 and CaCO3 at lower Earth mantle pressures and temperatures ranging between 34 and 45 GPa and between 2000 and 3000 K, respectively. The crystal structure was solved by single-crystal X-ray diffraction and contains carbon atoms tetrahedrally coordinated by oxygen. The tetrahedral CO4 4– groups form pyramidal [C4O10]4– complex anions by corner sharing. Raman spectroscopy allows an unambiguous identification of this compound, and the experimentally determined spectra are in excellent agreement with Raman spectra obtained from density functional theory calculations. CaC2O5-I4̅2d persists on pressure release down to ∼18 GPa at ambient temperature, where it decomposes into calcite and, presumably, CO2 under ambient conditions. As polymorphs of CaCO3 and CO2 are believed to be present in the vicinity of subducting slabs within Earth’s lower mantle, they would react to give CaC2O5-I4̅2d, which therefore needs to be considered instead of end-member CaCO3 in models of the mantle mineralogy.

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Structural, Physical, and Thermodynamic Properties of Aragonitic Ca_xSr_1–xCO₃ Solid Solutions

et al. 2021

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Single-phase Ca x Sr 1−x CO 3 solid solutions with an aragonite structure and x = 0−1 were obtained by precipitation synthesis and characterized with respect to their structural, physical, and thermodynamic properties. While there is no measurable excess volume of mixing, relaxation microcalorimetry showed a noticeable excess enthalpy of mixing, ΔH 298 ex . While the values determined here are much smaller than those obtained in an earlier study by solution calorimetry, they are consistent with the results of density functional theory (DFT)-based calculations. A combination of Raman spectroscopy and atomistic modeling confirms the finding based on the analysis of the diffraction data that there is no ordering of the Ca and Sr atoms. For the atomistic models, both quasirandom special structures and the virtual crystal approximation were employed. The dependence of the bulk modulus on composition was obtained by fitting an equation of state (EOS) to high-pressure synchrotron powder diffraction data and by DFT-based calculations, where stress−strain and compression data were employed. Both, the experimental and the DFT pressure-dependent data show an anomalous pressure-induced elongation of the baxis around 20−30 GPa, depending on composition, but no structural pressure-induced phase transition until 40 GPa, the highest pressure investigated here.

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Jannes König

Sr[C₂O₅] is an Inorganic Pyrocarbonate Salt with [C₂O₅]^2– Complex Anions

Sr₃[CO₄]O Antiperovskite with Tetrahedrally Coordinated sp³-Hybridized Carbon and OSr₆ Octahedra

Synthesis and Structure of Pb[C₂O₅]: An Inorganic Pyrocarbonate Salt

Novel Calcium sp³ Carbonate CaC₂O₅-I4̅2d May Be a Carbon Host in Earth’s Lower Mantle

Structural, Physical, and Thermodynamic Properties of Aragonitic Ca_xSr_1–xCO₃ Solid Solutions

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Jannes König

Sr[C2O5] is an Inorganic Pyrocarbonate Salt with [C2O5]2– Complex Anions

Sr3[CO4]O Antiperovskite with Tetrahedrally Coordinated sp3-Hybridized Carbon and OSr6 Octahedra

Synthesis and Structure of Pb[C2O5]: An Inorganic Pyrocarbonate Salt

Novel Calcium sp3 Carbonate CaC2O5-I4̅2d May Be a Carbon Host in Earth’s Lower Mantle

Structural, Physical, and Thermodynamic Properties of Aragonitic CaxSr1–xCO3 Solid Solutions

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Sr[C₂O₅] is an Inorganic Pyrocarbonate Salt with [C₂O₅]^2– Complex Anions

Sr₃[CO₄]O Antiperovskite with Tetrahedrally Coordinated sp³-Hybridized Carbon and OSr₆ Octahedra

Synthesis and Structure of Pb[C₂O₅]: An Inorganic Pyrocarbonate Salt

Novel Calcium sp³ Carbonate CaC₂O₅-I4̅2d May Be a Carbon Host in Earth’s Lower Mantle

Structural, Physical, and Thermodynamic Properties of Aragonitic Ca_xSr_1–xCO₃ Solid Solutions