Synthesis of Superconducting Cobalt Trihydride

Peña-Álvarez, Miriam; Li, Bin; Kelsall, Liam C.; Binns, Jack; Dalladay‐Simpson, Philip; Hermann, Andreas; Howie, Ross T.; Gregoryanz, Eugene

doi:10.1021/acs.jpclett.0c01807

Cited by 8 publications

(5 citation statements)

References 45 publications

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“…Recent reports of superconductivity approaching room temperature − have galvanized attempts to synthesize hydrogen-rich materials. Much effort is being invested to understand their crystal structures and properties. − However, high-temperature hydride superconductivity is associated not with a particular crystal structure but with the stabilization of dense atomic hydrogen over molecular dimers. − In this paper, we address the fundamental issue of whether hydrogen in metal hydrides is atomic or molecular. − Hydrides provide a unique challenge for structural studies, especially under high pressure. From the experimental side, a major challenge is the very weak X-ray scattering by hydrogen atoms.…”

Section: Introductionmentioning

confidence: 99%

“…Neither compound has an identifiable Raman contribution from the stretching H 2 mode. Therefore, barium hydrides represent an ideal system to study how the change in stoichiometry alters the H 2 molecule within the solid. − Thus, a systematic investigation of the mechanisms involved in hydrogen intra-molecular bond weakening and the influence of the metallic atomic number is here undertaken as the route to understand the concepts of bond-weakening and chemical pre-compression.…”

Section: Introductionmentioning

confidence: 99%

“… 14 − 16 In this paper, we address the fundamental issue of whether hydrogen in metal hydrides is atomic or molecular. 17 − 19 Hydrides provide a unique challenge for structural studies, especially under high pressure. From the experimental side, a major challenge is the very weak X-ray scattering by hydrogen atoms.…”

Section: Introductionmentioning

confidence: 99%

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H₂ Chemical Bond in a High-Pressure Crystalline Environment

Marqués,

Peña-Alvarez,

Martínez-Canales

et al. 2023

J. Phys. Chem. C

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We show that the hydrogen in metal superhydride compounds can adopt two distinct states�atomic and molecular. At low pressures, the maximum number of atomic hydrogens is typically equal to the valency of the cation; additional hydrogens pair to form molecules with electronic states far below the Fermi energy causing low-symmetry structures with large unit cells. At high pressures, molecules become unstable, and all hydrogens become atomic. This study uses density functional theory, adopting BaH 4 as a reference compound, which is compared with other stoichiometries and other cations. Increased temperature and zero-point motion also favor high-symmetry atomic states, and picosecond-timescale breaking and remaking of the bond permutations via intermediate H 3 − units.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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H₂ Chemical Bond in a High-Pressure Crystalline Environment

Marqués,

Peña-Alvarez,

Martínez-Canales

et al. 2023

J. Phys. Chem. C

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“…Phase transitions of TMDs can be induced by various external stimuli, such as mechanical exfoliation 8 , transverse electric eld 9 and intercalation 10 . Among these methods, applying pressure is a powerful and clean approach to modulate the electronic and crystal structures of TMDs without introducing impurities [11][12][13] . Taking the prototypal 2H phase (e.g.…”

Section: Introductionmentioning

confidence: 99%

Layer reconstruction, collapse and metallization of van der Waals bonded ZrS2 under high pressure

Hu,

Yang,

et al. 2023

Preprint

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In contrast to two-dimensional (2D) monolayer materials, van der Waals layered transition metal dichalcogenides exhibit rich polymorphism, making them promising candidates for novel superconductors, topological insulators, and high-performance electrochemical catalysts. Here, we combine Raman scattering, electrical conductivity, and synchrotron X-ray diffraction measurements to reveal a series of phase transitions in van der Waals layered ZrS2, driven by the formation of a distorted metastable structure under pressure. Unlike layered sliding observed in archetypal MoS2, ZrS2 undergoes a dramatic structural reconstruction, rearranging the original ZrS6 octahedra into ZrS8 cuboids at 5.5 GPa, leading to an abrupt 8.8% volume reduction. The unique cuboids coordination of Zr atoms in the single-layer is thermodynamically metastable and collapses to a partially disordered phase at 17.4 GPa, and ultimately metallize above 30.0 GPa. Decompressing metallic ZrS2 restores its semiconductor properties. These complex structural transitions present the highly tunable electronic properties of compressed ZrS2 with possible implications for optoelectronic devices.

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“…Phase transitions of TMDs are induced by various external stimuli, such as mechanical exfoliation 9 , transverse electric field 10 and intercalation 11 . Among these methods, applying pressure is a powerful and clean approach to modulate the electronic and crystal structures of TMDs without introducing impurities [12][13][14] . Taking the prototypal 2H phase (e.g.…”

mentioning

confidence: 99%

Deviatoric stress-induced metallization, layer reconstruction and collapse of van der Waals bonded zirconium disulfide

Yang,

Li,

Zhang

et al. 2024

Commun Chem

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In contrast to two-dimensional (2D) monolayer materials, van der Waals layered transition metal dichalcogenides exhibit rich polymorphism, making them promising candidates for novel superconductor, topological insulators and electrochemical catalysts. Here, we highlight the role of hydrostatic pressure on the evolution of electronic and crystal structures of layered ZrS2. Under deviatoric stress, our electrical experiments demonstrate a semiconductor-to-metal transition above 30.2 GPa, while quasi-hydrostatic compression postponed the metallization to 38.9 GPa. Both X-ray diffraction and Raman results reveal structural phase transitions different from those under hydrostatic pressure. Under deviatoric stress, ZrS2 rearranges the original ZrS6 octahedra into ZrS8 cuboids at 5.5 GPa, in which the unique cuboids coordination of Zr atoms is thermodynamically metastable. The structure collapses to a partially disordered phase at 17.4 GPa. These complex phase transitions present the importance of deviatoric stress on the highly tunable electronic properties of ZrS2 with possible implications for optoelectronic devices.

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Synthesis of Superconducting Cobalt Trihydride

Cited by 8 publications

References 45 publications

H₂ Chemical Bond in a High-Pressure Crystalline Environment

H₂ Chemical Bond in a High-Pressure Crystalline Environment

Layer reconstruction, collapse and metallization of van der Waals bonded ZrS2 under high pressure

Deviatoric stress-induced metallization, layer reconstruction and collapse of van der Waals bonded zirconium disulfide

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Synthesis of Superconducting Cobalt Trihydride

Cited by 8 publications

References 45 publications

H2 Chemical Bond in a High-Pressure Crystalline Environment

H2 Chemical Bond in a High-Pressure Crystalline Environment

Layer reconstruction, collapse and metallization of van der Waals bonded ZrS2 under high pressure

Deviatoric stress-induced metallization, layer reconstruction and collapse of van der Waals bonded zirconium disulfide

Contact Info

Product

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H₂ Chemical Bond in a High-Pressure Crystalline Environment

H₂ Chemical Bond in a High-Pressure Crystalline Environment