Universal Dynamical Onset in Water at Distinct Material Interfaces

Overview

Journal Chem Sci

Publisher Royal Society of Chemistry

Specialty Chemistry

Date 2022 May 5

PMID 35509458

Authors

Lirong Zheng

Zhuo Liu

Qiang Zhang

Song Li

Juan Huang

Lei Zhang

Bing Zan

Madhusudan Tyagi

He Cheng

Taisen Zuo

Victoria Garcia Sakai

Takeshi Yamada

Chenxing Yang

Pan Tan

Fan Jiang

Hao Chen

Wei Zhuang

Liang Hong

Affiliations

Soon will be listed here.

Abstract

Interfacial water remains liquid and mobile much below 0 °C, imparting flexibility to the encapsulated materials to ensure their diverse functions at subzero temperatures. However, a united picture that can describe the dynamical differences of interfacial water on different materials and its role in imparting system-specific flexibility to distinct materials is lacking. By combining neutron spectroscopy and isotope labeling, we explored the dynamics of water and the underlying substrates independently below 0 °C across a broad range of materials. Surprisingly, while the function-related anharmonic dynamical onset in the materials exhibits diverse activation temperatures, the surface water presents a universal onset at a common temperature. Further analysis of the neutron experiment and simulation results revealed that the universal onset of water results from an intrinsic surface-independent relaxation: switching of hydrogen bonds between neighboring water molecules with a common energy barrier of ∼35 kJ mol.

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