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引用次数: 0
摘要
在低温压缩条件下,冰 I 会发生蜕变,但不会转化为其他高压冰晶。过高的压力会导致其塌缩为高密度无定形冰(HDA),在加热时主要转化为冰 IV 或 XII。了解如何避免压力诱导的非晶化以及优先成核的可转移相的分子起源,有助于深入了解 HDA 的性质。在此,我们进行了分子动力学(MD)模拟,证明当六方冰(冰Ih)表现出特定的氢有序时,氢有序的冰Ih可以通过部分有序的HDA转化为冰XII。该结晶区域被确定为一种未报道的冰形态(命名为冰 M),其五边形螺旋氢键网络与冰 XII 中的氢键网络相同。残留的冰 M 构型促进了 HDA 向冰 XII 的转变。结合我们之前对冰 Ic 的氢有序形式的研究,冰 I 中的氢有序似乎能够实现晶体到晶体的转变,无论是直接转变还是间接转变,甚至在低温下也是如此。
Hydrogen Ordering in Ice Ih Facilitates the Transition from HDA to Ice XII
Under low-temperature compression, ice I becomes metastable but does not transform into other high-pressure ice crystals. Excess pressure results in its collapse to high-density amorphous ice (HDA), which predominantly transforms into ice IV or XII upon heating. Understanding how to avoid pressure-induced amorphization and molecular origin prioritizing nucleation of a metastable phase provides insights into the nature of HDA. Here, we perform molecular dynamics (MD) simulations to demonstrate that when hexagonal ice (ice Ih) exhibits a particular hydrogen ordering, the hydrogen-ordered ice Ih can transform into ice XII via a partially ordered HDA. The crystalline region is identified as an unreported ice form (named ice M) with pentagonal-helical hydrogen-bond networks identical to those in ice XII. The remanent ice M configuration facilitates the transition of HDA to ice XII. Combined with our previous study on a hydrogen-ordered form of ice Ic, hydrogen ordering in ice I appears to enable crystal-to-crystal transitions, whether direct or indirect, even at low temperatures.
期刊介绍:
The Journal of Physical Chemistry A/B/C is devoted to reporting new and original experimental and theoretical basic research of interest to physical chemists, biophysical chemists, and chemical physicists.
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