Kinetic analysis of complex physico-chemical processes
Provider: Grantová agentura ČR
Programme: Standardní projekty
Implementation period: 01.01.17 - 31.12.19
Workplace:
Fakulta chemicko-technologická - KFCh/věda z MŠMT
Investigator: Svoboda RomanTeam member: Košťálová Daniela | Zmrhalová Zuzana
Description:
Nowadays, kinetic analysis of complex processes is of major interest for scientists dealing with solid-state kinetics. Complex processes can be characterized as those during which at least two different mechanisms proceed simultaneously ? most solid-state processes are in fact complex. However, routine application of complex kinetic analysis is restrained by the lack of concrete methodologies and procedural standards. The only developed approach involves extremely time-consuming random testing of extensive number of different models combinations, which makes the routine virtually impossible to apply in practice. Main objective of the introduced grant project is a systematic study of complex kinetic processes and their mutual dependences (both theoretically and experimentally) and a development, optimization and verification of a general algorithm for quick and effective determination of the most probable complex kinetic mechanism. Extensive testing of the algorithm for various real-life complex solid-state processes will be performed.
Nowadays, kinetic analysis of complex processes is of major interest for scientists dealing with solid-state kinetics. Complex processes can be characterized as those during which at least two different mechanisms proceed simultaneously ? most solid-state processes are in fact complex. However, routine application of complex kinetic analysis is restrained by the lack of concrete methodologies and procedural standards. The only developed approach involves extremely time-consuming random testing of extensive number of different models combinations, which makes the routine virtually impossible to apply in practice. Main objective of the introduced grant project is a systematic study of complex kinetic processes and their mutual dependences (both theoretically and experimentally) and a development, optimization and verification of a general algorithm for quick and effective determination of the most probable complex kinetic mechanism. Extensive testing of the algorithm for various real-life complex solid-state processes will be performed.
