蛋白质水化水中的低温动态交叉现象：模拟与实验

The low-temperature dynamic crossover phenomenon in protein hydration water: simulations vs experiments.

作者信息

Lagi Marco, Chu Xiangqiang, Kim Chansoo, Mallamace Francesco, Baglioni Piero, Chen Sow-Hsin

机构信息

Department of Nuclear Science and Engineering, Massachusetts Institute of Technology, Cambridge, MA 02139, USA.

出版信息

J Phys Chem B. 2008 Feb 14;112(6):1571-5. doi: 10.1021/jp710714j. Epub 2008 Jan 19.

DOI:10.1021/jp710714j

PMID:18205352

Abstract

A super-Arrhenius-to-Arrhenius dynamic crossover phenomenon has been observed in the translational alpha-relaxation time and in the inverse of the self-diffusion constant both experimentally and by simulations for lysozyme hydration water in the temperature range of TL = 223 +/- 2 K. MD simulations are based on a realistic hydrated powder model, which uses the TIP4P-Ew rigid molecular model for the hydration water. The convergence of neutron scattering, nuclear magnetic resonance and molecular dynamics simulations supports the interpretation that this crossover is a result of the gradual evolution of the structure of hydration water from a high-density liquid to a low-density liquid form upon crossing of the Widom line above the possible liquid-liquid critical point of water.

摘要

在223±2K的温度范围内，通过实验和模拟，在溶菌酶水合水的平移α弛豫时间和自扩散常数的倒数中均观察到了一种超阿累尼乌斯到阿累尼乌斯的动态交叉现象。分子动力学模拟基于一个真实的水合粉末模型，该模型使用TIP4P-Ew刚性分子模型来描述水合水。中子散射、核磁共振和分子动力学模拟的结果相互印证，支持了这样一种解释：这种交叉现象是由于在越过水的可能液-液临界点上方的威多姆线时，水合水的结构从高密度液体逐渐演变为低密度液体形式所导致的。

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蛋白质水化水中的低温动态交叉现象：模拟与实验

The low-temperature dynamic crossover phenomenon in protein hydration water: simulations vs experiments.

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