Stabilizing a high-pressure phase in InSb at ambient conditions with a laser-driven pressure pulse

2); 2) ((1) MAX IV Laboratory; (2) Department of Physics; (3) ESRF The European Synchrotron; (4) CELIA (Centre Lasers Intenses et Applications); A. I. H. Persson (2); A. Jarnac (1; A. Jurgilaitis (1); A. U. J Bengtsson (2); CEA

arxiv: 1712.05370 · v1 · pith:NOYOTRAVnew · submitted 2017-12-14 · ❄️ cond-mat.mtrl-sci

Stabilizing a high-pressure phase in InSb at ambient conditions with a laser-driven pressure pulse

A. Jarnac (1 , 2) , Xiaocui Wang (2) , A. U. J Bengtsson (2) , M. Burza (1) , J. C. Ekstrom (2) , H. Enquist (1) , A. Jurgilaitis (1)

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N. Kretzschmar (3) A. I. H. Persson (2) C. M. Tu (2) M. Wulff (3) F. Dorchies (4) J. Larsson (1 2) ((1) MAX IV Laboratory Lund University Sweden (2) Department of Physics (3) ESRF The European Synchrotron Grenoble France (4) CELIA (Centre Lasers Intenses et Applications) Univ. Bordeaux CNRS CEA Talence France)

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classification ❄️ cond-mat.mtrl-sci

keywords insb-iinsb-iiiphaseorthorhombictransitionambientcellconditions

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In this letter, we describe the stabilization of indium antimonide (InSb) in the high-pressure orthorhombic phase (InSb-III) at ambient conditions. Until now, InSb-III has only been observed above 9 GPa, or at around 3 GPa as a metastable structure during the phase transition from cubic zinc blende (InSb-I) to orthorhombic InSb-IV. The crystalline phase transition from InSb-I to InSb-III was driven by an ultrashort, laser-generated, non-hydrostatic pressure pulse. The transition occurred in preferred orientations locked to the initial orientation of the InSb-I crystal, breaking the symmetry of the InSb-I cubic cell to form the InSb-III orthorhombic cell.

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Stabilizing a high-pressure phase in InSb at ambient conditions with a laser-driven pressure pulse

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