TY - UNPB
T1 - Dynamics, Structure and Glass Formation of Calcium Aluminate Liquids
AU - Liu, Hao
AU - Pan, Ruikun
AU - Chen, Wenlin
AU - Shan, Zhitao
AU - Qiao, Ang
AU - Jahn, Sandro
AU - Drewitt, James W. E.
AU - Hennet, Louis
AU - Langstaff, David P.
AU - Tao, Haizheng
AU - Greaves, G. Neville
AU - Yue, Yuanzheng
N1 - 14 pages, 4 figures
PY - 2017/12/22
Y1 - 2017/12/22
N2 - Crystalline calcium-aluminates include the phases essential in the setting of Portland cements developed over the last century. It is only within recent decades, however, that calcium-aluminate melts and glasses have begun to attract attention, bringing new functionalities in photonic and electronic applications. These studies, though, have been limited to compositions close to a deep eutectic from where glasses easily form. With the development of contactless levitation furnaces the glass forming region can now be hugely extended. We have taken advantage of these developments to rationalise, for the first time, melt rheology with structural properties across this expanded compositional range, substantiating this with atomistic simulation. In the process, we have discovered that supercooled calcium-aluminates comprise a new system where fragile-to-strong phase transitions are ubiquitous. Taking this holistic approach, we have quantified the common basis of thermo-physical and structural diversity in this novel glass-forming system, together with its inherent polyamorphism.
AB - Crystalline calcium-aluminates include the phases essential in the setting of Portland cements developed over the last century. It is only within recent decades, however, that calcium-aluminate melts and glasses have begun to attract attention, bringing new functionalities in photonic and electronic applications. These studies, though, have been limited to compositions close to a deep eutectic from where glasses easily form. With the development of contactless levitation furnaces the glass forming region can now be hugely extended. We have taken advantage of these developments to rationalise, for the first time, melt rheology with structural properties across this expanded compositional range, substantiating this with atomistic simulation. In the process, we have discovered that supercooled calcium-aluminates comprise a new system where fragile-to-strong phase transitions are ubiquitous. Taking this holistic approach, we have quantified the common basis of thermo-physical and structural diversity in this novel glass-forming system, together with its inherent polyamorphism.
KW - cond-mat.mtrl-sci
M3 - Preprint
BT - Dynamics, Structure and Glass Formation of Calcium Aluminate Liquids
ER -