Structural Evolution of Compressing Amorphous Ice

Chin. Phys. Lett.

2007, Vol. 24

Issue (4): 1099-1102 DOI:

Original Articles

Structural Evolution of Compressing Amorphous Ice

WANG Yan;DONG Shun-Le

Department of Physics, Ocean University of China, Qingdao 266100

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WANG Yan, DONG Shun-Le 2007 Chin. Phys. Lett. 24 1099-1102

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Abstract

Molecular dynamics simulation is employed to study structural evolution
during compressing low density amorphous ice from one atmosphere to
2.5GPa. The calculated results show that high density amorphous ice is
formed under intermediate pressure of about 1.0GPa and O--O--O angle
ranges from about 83° to 113° and O--H...O is bent from 112° to 160°. The very high density amorphous ice is also formed under the pressure larger than 1.4GPa and interstitial molecules are found in 0.3--0.4Å just beyond the nearest O--O distance. Low angle O--H...O disappears and it is believed that
these hydrogen bonds are broken or re-bonded under high pressures.

Keywords: 83.20.Jp 61.43.-j 64.70.Kb 61.20.Ja

Received: 11 September 2006 Published: 26 March 2007

PACS:	83.20.Jp
	61.43.-j	(Disordered solids)
	64.70.Kb
	61.20.Ja	(Computer simulation of liquid structure)

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