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ABSTRACT
The polyamorphism of liquid silica (SiO2) at 3200 K and in a wide pressure range is investigated by molecular dynamics simulation. Results show that the structure of liquid SiO2 consists of five order-parameters that do not depend on compression. Three order parameters that relate to the short-range order are SiOx coordination units (x = 4, 5, 6) and two order parameters that relate to the intermediate-range order are OSi2 and OSi3 linkages. The structure of liquid silica under compression can be described by the two-state model: low-density and high-density states. The low-density state is formed by clustering of OSi2 linkages (in the low-density state, the short-range order (SRO) is mainly characterized by SiO4 coordination units), conversely, clustering of OSi3 linkages will form high-density state (in the high-density state, the SRO is mainly characterized by SiO5 and SiO6 coordination units). Under compression, in the liquid silica co-exist two phases: low-density and high-density phases. The size of phase regions significantly depends on compression.
Disclosure statement
No potential conflict of interest was reported by the authors.
Notes on contributors
L. T San received her master degree in Engineering Physics from School of Engineering Physics (SEP), Hanoi University of Science and Technology (HUST). At present, she is studying PhD program at SEP.
N. V. Hong is an Associate Professor at SEP, HUST. He is a lecturer at SEP. He has teaching experience of more than 10 years to students of computational physics and 50 national/international publications in the field of material science.
P. K. Hung is an Associate Professor at SEP, HUST. He is the Head of the Department of Computational Physics. He has teaching experience of more than 20 years to students, masters, PhDs of computational physics and 80 national/international publications in the field of material science.