Through a systematic structural search we found an allotrope of carbon with
Cmmm symmetry which we predict to be more stable than graphite for pressures
above 10 GPa. This material, which we refer to as Z-carbon, is formed by pure
sp3 bonds and is the only carbon allotrope which provides an excellent match to
unexplained features in experimental X-ray diffraction and Raman spectra of
graphite under pressure. The transition from graphite to Z-carbon can occur
through simple sliding and buckling of graphene sheets. Our calculations
predict that Z-carbon is a transparent wide band gap semiconductor with a
hardness comparable to diamond.Comment: 4 pages, 5 figure

Amsler, Maximilian

Balima, Felix

Botti, Silvana

Caliste, Damien

Flores-Livas, José A.

Ghasemi, S. Alireza

Goedecker, Stefan

Lehtovaara, Lauri

Machon, Denis

Marques, Miguel A. L.

Miguel, Alfonso San

Pailhès, Stéphane

Willand, Alexander

Physical Review Letters

English

arXiv

Flores-Livas, Jose A.

Balima, Félix

Alireza Ghasemi, S.

Pailhes, Stephane

San Miguel, Alfonso

HAL Descartes

Crystal Structure of Cold Compressed Graphite

HAL-CEA

Maximilian Amsler

José A. Flores-Livas

Lauri Lehtovaara

Felix Balima

S. Alireza Ghasemi

Denis Machon

Stéphane Pailhès

Alexander Willand

Damien Caliste

Silvana Botti

Alfonso San Miguel

Stefan Goedecker

Miguel A. L. Marques

Crossref

Thomas J. Lenosky

High-Pressure Structures of Disilane and Their Superconducting Properties

Hal - Université Grenoble Alpes

HAL: Hyper Article en Ligne

A systematic ab initio search for low-enthalpy phases of disilane (Si2H6) at high pressures was performed based on the minima hopping method. We found a novel metallic phase of disilane with Cmcm symmetry, which is enthalpically more favorable than the recently proposed structures of disilane up to 280 GPa, but revealing compositional instability below 190 GPa. The Cmcm phase has a moderate electron-phonon coupling yielding a superconducting transition temperature T-c of around 20 K at 100 GPa, decreasing to 13 K at 220 GPa. These values are significantly smaller than previously predicted T-c's for disilane at equivalent pressure. This shows that similar but different crystalline structures of a material can result in dramatically different T-c's and stresses the need for a systematic search for a crystalline ground state

Lenosky, Thomas J.

edoc

HAL-Polytechnique