Lecture 1: INTERACTION IN THE SYSTEM Li2O-TiO2-MnxOy; Lecture 2:STRUCTURE FORMATION IN EUTECTIC COMPOSITES: PHASE FIELD SIMULATIONS
SEMINAR
The State Key Lab of High Performance Ceramics and Superfine Microstructure
Structural Ceramics Engineering Research Center
中国科学院上海硅酸盐研究所
Lecture 1: INTERACTION IN THE SYSTEM Li2O-TiO2-MnxOy
Speaker:Dr. Sci. Sergij Lakiza
Institute for Problems in Materials Science, National Academy of Sciences of Ukraine
Lecture 2:STRUCTURE FORMATION IN EUTECTIC COMPOSITES: PHASE FIELD SIMULATIONS
Speaker:Prof. Oleksiy Bystrenko
Institute for Problems in Materials Science, National Academy of Sciences of Ukraine
时间:6月27日(周四)下午13:30
地点:嘉定园区G3第一会议室
联系人:张景贤研究员,刘建军研究员
Lecture 1:INTERACTION IN THE SYSTEM Li2O-TiO2-MnxOy
1. What is Li-batteries?
2. Why the system Li2O-TiO2-MnO?
3. What is phase diagram?
4. The system Li2O-TiO2-MnO
5. The influence of alternative atom valence.
6. Constructing of preliminary phase diagram.
7. First experimental results.
8. Comparison of preliminary phase diagram construction results in thsystems with different Mn valence.
9. Resume and further development.
Lecture 2:STRUCTURE FORMATION IN EUTECTIC COMPOSITES: PHASE FIELD SIMULATIONS
Abstract :The idea of how to use the phase field theory for the description of structure in eutectic composites is illustrated at an example of LaB6-ZrB2 ceramics. Computer simulations of structurization in boride–boride ceramics are performed using the standard version of phase-field theory. The simulations reproduce the main properties of eutectic structures observed in experiments, i.e., spatial segregation of components, structure formation from an overcooled melt, and complete decomposition of the system when it relaxes toward thermodynamic equilibrium. The eutectic colonies formed in the process of directional solidification and the dependence of spatial parameter of the emerging structures on the solidification rate are reproduced as well. The simulations demonstrate that the ordered fibrous structures are formed only in a certain range of solidification rates. In addition, the the use of multicomponent phase field theory is illustrated at an example of a 3-component model eutectic system.