Abstract

The proton conductivity of a dense coordination polymer (CP) was investigated under high-pressure conditions. Impedance measurements under high pressures revealed that the proton conductivity of the CP decreased more than 1000-fold at pressures of 3–7 GPa and that the activation energy for proton conduction almost doubled compared with that at ambient pressure. A synchrotron X-ray study under high pressure identified the amorphization process of the CP during compression, which rationally explains the decrease in conductivity and increase in activation energy. This phenomenon is categorized as reversible pressure-induced amorphization of a dense CP and is regarded as a demonstration of the coupling of the mechanical and electrical properties of a CP.

Highlights

  • Articles you may be interested in Pressure-induced amorphization in orthorhombic Ta2O5: An intrinsic character of crystal

  • Impedance measurements under high pressures revealed that the proton conductivity of the coordination polymer (CP) decreased more than 1000-fold at pressures of 3–7 GPa and that the activation energy for proton conduction almost doubled compared with that at ambient pressure

  • A synchrotron X-ray study under high pressure identified the amorphization process of the CP during compression, which rationally explains the decrease in conductivity and increase in activation energy

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Summary

Introduction

Pressure-induced amorphization of a dense coordination polymer and its impact on proton conductivity The proton conductivity of a dense coordination polymer (CP) was investigated under high-pressure conditions.

Results
Conclusion

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