Atomic structure of Mg-based metallic glasses from molecular dynamics and neutron diffraction

Anastasia Gulenko; Louis Forto Chungong; Junheng Gao; Iain Todd; Alex C. Hannon; Richard A. Martin; Jamieson K. Christie

doi:10.1039/C6CP03261C

Atomic structure of Mg-based metallic glasses from molecular dynamics and neutron diffraction

Anastasia Gulenko, Louis Forto Chungong, Junheng Gao, Iain Todd, Alex C. Hannon, Richard A. Martin^*, Jamieson K. Christie

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

We use a combination of classical molecular dynamics simulation and neutron diffraction to identify the atomic structure of five different Mg–Zn–Ca bulk metallic glasses, covering a range of compositions with substantially different behaviour when implanted in vitro. There is very good agreement between the structures obtained from computer simulation and those found experimentally. Bond lengths and the total correlation function do not change significantly with composition. The zinc and calcium bonding shows differences between composition: the distribution of Zn–Ca bond lengths becomes narrower with increasing Zn content, and the preference for Zn and Ca to avoid bonding to themselves or each other becomes less strong, and, for Zn–Ca, transforms into a positive preference to bond to each other. This transition occurs at about the same Zn content at which the behaviour on implantation changes, hinting at a possible structural connection. A very broad distribution of Voronoi polyhedra are also found, and this distribution broadens with increasing Zn content. The efficient cluster packing model, which is often used to describe the structure of bulk metallic glasses, was found not to describe these systems well.

Original language	English
Pages (from-to)	8504-8515
Number of pages	12
Journal	Physical Chemistry Chemical Physics
Volume	19
Issue number	12
Early online date	3 Mar 2017
DOIs	https://doi.org/10.1039/C6CP03261C
Publication status	Published - 28 Mar 2017

Bibliographical note

Funding: ISIS Pulsed Neutron and Muon Source for the allocation of beam-time (RB1510188); EPSRC (EP/L024195 and EP/L000202)

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title = "Atomic structure of Mg-based metallic glasses from molecular dynamics and neutron diffraction",

abstract = "We use a combination of classical molecular dynamics simulation and neutron diffraction to identify the atomic structure of five different Mg–Zn–Ca bulk metallic glasses, covering a range of compositions with substantially different behaviour when implanted in vitro. There is very good agreement between the structures obtained from computer simulation and those found experimentally. Bond lengths and the total correlation function do not change significantly with composition. The zinc and calcium bonding shows differences between composition: the distribution of Zn–Ca bond lengths becomes narrower with increasing Zn content, and the preference for Zn and Ca to avoid bonding to themselves or each other becomes less strong, and, for Zn–Ca, transforms into a positive preference to bond to each other. This transition occurs at about the same Zn content at which the behaviour on implantation changes, hinting at a possible structural connection. A very broad distribution of Voronoi polyhedra are also found, and this distribution broadens with increasing Zn content. The efficient cluster packing model, which is often used to describe the structure of bulk metallic glasses, was found not to describe these systems well.",

author = "Anastasia Gulenko and {Forto Chungong}, Louis and Junheng Gao and Iain Todd and Hannon, {Alex C.} and Martin, {Richard A.} and Christie, {Jamieson K.}",

note = "Funding: ISIS Pulsed Neutron and Muon Source for the allocation of beam-time (RB1510188); EPSRC (EP/L024195 and EP/L000202)",

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doi = "10.1039/C6CP03261C",

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AU - Gulenko, Anastasia

AU - Forto Chungong, Louis

AU - Gao, Junheng

AU - Todd, Iain

AU - Hannon, Alex C.

AU - Martin, Richard A.

AU - Christie, Jamieson K.

N1 - Funding: ISIS Pulsed Neutron and Muon Source for the allocation of beam-time (RB1510188); EPSRC (EP/L024195 and EP/L000202)

PY - 2017/3/28

Y1 - 2017/3/28

N2 - We use a combination of classical molecular dynamics simulation and neutron diffraction to identify the atomic structure of five different Mg–Zn–Ca bulk metallic glasses, covering a range of compositions with substantially different behaviour when implanted in vitro. There is very good agreement between the structures obtained from computer simulation and those found experimentally. Bond lengths and the total correlation function do not change significantly with composition. The zinc and calcium bonding shows differences between composition: the distribution of Zn–Ca bond lengths becomes narrower with increasing Zn content, and the preference for Zn and Ca to avoid bonding to themselves or each other becomes less strong, and, for Zn–Ca, transforms into a positive preference to bond to each other. This transition occurs at about the same Zn content at which the behaviour on implantation changes, hinting at a possible structural connection. A very broad distribution of Voronoi polyhedra are also found, and this distribution broadens with increasing Zn content. The efficient cluster packing model, which is often used to describe the structure of bulk metallic glasses, was found not to describe these systems well.

AB - We use a combination of classical molecular dynamics simulation and neutron diffraction to identify the atomic structure of five different Mg–Zn–Ca bulk metallic glasses, covering a range of compositions with substantially different behaviour when implanted in vitro. There is very good agreement between the structures obtained from computer simulation and those found experimentally. Bond lengths and the total correlation function do not change significantly with composition. The zinc and calcium bonding shows differences between composition: the distribution of Zn–Ca bond lengths becomes narrower with increasing Zn content, and the preference for Zn and Ca to avoid bonding to themselves or each other becomes less strong, and, for Zn–Ca, transforms into a positive preference to bond to each other. This transition occurs at about the same Zn content at which the behaviour on implantation changes, hinting at a possible structural connection. A very broad distribution of Voronoi polyhedra are also found, and this distribution broadens with increasing Zn content. The efficient cluster packing model, which is often used to describe the structure of bulk metallic glasses, was found not to describe these systems well.

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JO - Physical Chemistry Chemical Physics

JF - Physical Chemistry Chemical Physics

IS - 12

ER -

Atomic structure of Mg-based metallic glasses from molecular dynamics and neutron diffraction

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