Polymerization degree
theory and traditional charge compensation
theory are the most fundamental principles to understand the structure
and properties of oxide melts. It can well explain the behavior characteristics
of acidic oxides and basic oxides in a melt. However, the amphoteric
behavior of oxides cannot be explained well by these two theories.
Herein, the octahedral connection mode and the behavior of the amphoteric
transition of TiO2 are analyzed by molecular dynamics simulation,
and then, a calculation model which can quantitatively calculate the
amphoteric transition of the oxide is established by analyzing a large
number of data. On the basis of the model, a novel theory of supply
and demand is put forward, which can explain the amphoteric transition
behavior of oxides very well. To a great extent, the supply and demand
theory makes up for the deficiency of the atomic structure theory
of oxide melts and provides mechanism explanation and model prediction
for the oxide amphoteric transformation behavior.