Litcius/Paper detail

Superconductivity in Compression-Shear Deformed Diamond

Chang Liu, Xianqi Song, Quan Li, Yanming Ma, Changfeng Chen

2020Physical Review Letters112 citationsDOIOpen Access PDF

Abstract

Diamond is a prototypical ultrawide band gap semiconductor, but turns into a superconductor with a critical temperature T_{c}≈4 K near 3% boron doping [E. A. Ekimov et al., Nature (London) 428, 542 (2004)NATUAS0028-083610.1038/nature02449]. Here we unveil a surprising new route to superconductivity in undoped diamond by compression-shear deformation that induces increasing metallization and lattice softening with rising strain, producing phonon mediated T_{c} up to 2.4-12.4 K for a wide range of Coulomb pseudopotential μ^{*}=0.15-0.05. This finding raises intriguing prospects of generating robust superconductivity in strained diamond crystal, showcasing a distinct and hitherto little explored approach to driving materials into superconducting states via strain engineering. These results hold promise for discovering superconductivity in normally nonsuperconductive materials, thereby expanding the landscape of viable nontraditional superconductors and offering actionable insights for experimental exploration.

Topics & Concepts

SuperconductivityDiamondCondensed matter physicsPseudopotentialMaterials scienceSemiconductorPhononSofteningShear (geology)DopingCoulombEngineering physicsPhysicsComposite materialOptoelectronicsQuantum mechanicsElectronDiamond and Carbon-based Materials ResearchHigh-pressure geophysics and materialsSuperconductivity in MgB2 and Alloys