Rigidity‐Driven Structural Isomers in the NaCl–Ga2S3 System: Implications for Energy Storage
Maria Bokova,
Mohammad Kassem,
Takeshi Usuki,
Andrey Tverjanovich,
Anton Sokolov,
Daniele Fontanari,
Alex C. Hannon,
Chris J. Benmore,
Igor Alekseev,
Shinji Kohara,
Pascal Roussel,
Maxim Khomenko,
Koji Ohara,
Yohei Onodera,
Arnaud Cuisset,
Eugene Bychkov
Affiliations
Maria Bokova
Laboratoire de Physico‐Chimie de l’Atmosphère Université du Littoral Côte d’Opale Dunkerque 59140 France
Mohammad Kassem
Laboratoire de Physico‐Chimie de l’Atmosphère Université du Littoral Côte d’Opale Dunkerque 59140 France
Takeshi Usuki
Faculty of Science Yamagata University Yamagata 990‐8560 Japan
Andrey Tverjanovich
Institute of Chemistry St. Petersburg State University St. Petersburg 198504 Russia
Anton Sokolov
Laboratoire de Physico‐Chimie de l’Atmosphère Université du Littoral Côte d’Opale Dunkerque 59140 France
Daniele Fontanari
Laboratoire de Physico‐Chimie de l’Atmosphère Université du Littoral Côte d’Opale Dunkerque 59140 France
Alex C. Hannon
ISIS Facility Rutherford Appleton Laboratory Chilton Didcot OX11 0QX UK
Chris J. Benmore
X‐ray Science Division Advanced Photon Source Argonne National Laboratory Lemont IL 60439 USA
Igor Alekseev
Laboratoire de Physico‐Chimie de l’Atmosphère Université du Littoral Côte d’Opale Dunkerque 59140 France
Shinji Kohara
Quantum Beam Diffraction Group Center for Basic Research on Materials National Institute for Materials Science 1‐1‐1 Kouto, Sayo‐cho, Sayo‐gun Hyogo 679‐5148 Japan
Pascal Roussel
Unité de Catalyse et de Chimie du Solide (UCCS) Université de Lille CNRS, Centrale Lille, Université d’Artois 59000 Lille France
Maxim Khomenko
Faculty of Physics Lomonosov Moscow State University Moscow 119991 Russia
Koji Ohara
Faculty of Materials for Energy Shimane University 1060, Nishi‐Kawatsu‐Cho Matsue Shimane 690‐8504 Japan
Yohei Onodera
Quantum Beam Diffraction Group Center for Basic Research on Materials National Institute for Materials Science 1‐1‐1 Kouto, Sayo‐cho, Sayo‐gun Hyogo 679‐5148 Japan
Arnaud Cuisset
Laboratoire de Physico‐Chimie de l’Atmosphère Université du Littoral Côte d’Opale Dunkerque 59140 France
Eugene Bychkov
Laboratoire de Physico‐Chimie de l’Atmosphère Université du Littoral Côte d’Opale Dunkerque 59140 France
Alternative energy sources require the search for innovative materials with promising functionalities. Systems with unusual chemical properties represent an insufficiently explored domain, concealing unexpected features. Using diffraction and Raman spectroscopy over a wide temperature range, supported by first‐principles simulations, a rare phenomenon is unveiled: phase‐dependent chemical interactions between binary components in the NaCl–Ga2S3 system. In this unique occurrence, previously intact binary crystalline species transform upon melting into mixed liquid structural isomers, forming bonds with new partners. The chemical combinatorics appears to be fully reversible for stable crystals and liquids. Despite this, rapidly frozen glasses out of thermodynamic equilibrium remain in a metastable isomeric state, offering remarkable properties, particularly a high room‐temperature Na+ conductivity, comparable to the best sodium halide superionic conductors and therefore encouraging for sodium solid‐state batteries and energy applications. A rigidity paradigm is responsible for the observed phenomenon, as the extremely constrained Ga2S3 crystal lattice does not survive viscous flow, breaking up at a short‐range level. The removal of rigidity constraints and dense packing leads to a significant increase in empty space, which is the origin of high sodium diffusivity. Broadly, the rigidity‐driven structural isomerism opens up an inspiring path to the discovery of atypical materials.
