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High-pressure reversibility in a plastically flexible coordination polymer crystal

Xiaojiao Liu, Adam A. L. Michalchuk∞, Biswajit Bhattacharya, Nobuhiro Yasuda, Franziska Emmerling, Colin R. Pulham

2021Nature Communications35 citationsDOIOpen Access PDF

Abstract

Abstract Single crystals which exhibit mechanical flexibility are promising materials for advanced technological applications. Before such materials can be used, a detailed understanding of the mechanisms of bending is needed. Using single crystal X-ray diffraction and microfocus Raman spectroscopy, we study in atomic detail the high-pressure response of the plastically flexible coordination polymer [Zn(μ-Cl) 2 (3,5-dichloropyridine) 2 ] n ( 1 ). Contradictory to three-point bending, quasi-hydrostatic compression of ( 1 ) is completely reversible, even following compression to over 9 GPa. A structural phase transition is observed at ca . 5 GPa. DFT calculations show this transition to result from the pressure-induced softening of low-frequency vibrations. This phase transition is not observed during three-point-bending. Microfocus synchrotron X-ray diffraction revealed that bending yields significant mosaicity, as opposed to compression. Hence, our studies indicate of overall disparate mechanical responses of bulk flexibility and quasi-hydrostatic compression within the same crystal lattice. We suspect this to be a general feature of plastically bendable materials.

Topics & Concepts

Materials scienceBendingPhase transitionHydrostatic pressureDiffractionRaman spectroscopyCompression (physics)Single crystalCrystallographyCrystal (programming language)Composite materialCondensed matter physicsOpticsChemistryThermodynamicsComputer sciencePhysicsProgramming languageCrystallography and molecular interactionsOrganic and Molecular Conductors ResearchOrganometallic Compounds Synthesis and Characterization