(in Polish) Advanced chemical kinetics WM-CH-S2-E2-ACK
Lista zagadnień (dla wykładów i ćwiczeń):
1. Scope and purpose of chemical kinetics.
2. Brief summary of classical formal kinetics.
3. The limitations of classical kinetics.
4. Physical aspects of the molecular response to fast perturbations.
5. Modern experiments in chemical kinetics.
6. A reminder of mathematical concepts.
7. Molecular diffusion in homogeneous media.
8. Diffusion assisted chemical reactions.
9. Proton, Energy and Electron transfer.
10. Consecutive irreversible reactions in presence of diffusion.
11. Reversible reactions: the total breakdown of the rate constant concept.
12. Heterogeneous and anisotropic media; biological crowding.
13. Distribution of rate constants and dispersive kinetics.
14. Protein folding, Nucleation and Polymers.
15. Open questions in chemical kinetics.
(in Polish) Dyscyplina naukowa, do której odnoszą się efekty uczenia się
(in Polish) E-Learning
(in Polish) Grupa przedmiotów ogólnouczenianych
Subject level
Learning outcome code/codes
Type of subject
Preliminary Requirements
Course coordinators
Learning outcomes
EK1. Identifies those cases in which the classical kinetics approach is not appropriate
EK2. Selects the best approach to solve problems related to chemical kinetics
ECTS distribution for lectures:
classwork: 30h, 1ECTS
consultation with teacher: 10h, 0,4ECTS
preparing for classwork: 10h, 0,4ECTS
preparing for verification: 5h, 0,2ECTS
ECTS distribution for exercises:
classwork: 30h, 1ECTS
consultation with teacher: 10h, 0,4ECTS
preparing for classwork: 10h, 0,4ECTS
preparing for verification: 5h, 0,2ECTS
Assessment criteria
EK1:
5.0: verification indicates that the student without noticeable imperfections identifies those cases in which the classical kinetics approach is not appropriate
4.5: verification indicates that the student almost correctly identifies those cases in which the classical kinetics approach is not appropriate and does not fulfil the higher grede requirements
4.0: verification indicates that the student substentially identifies those cases in which the classical kinetics approach is not appropriate and does not fulfil the higher grede requirements
3.5: verification indicates that the student substentially but inconsitently identifies those cases in which the classical kinetics approach is not appropriate and does not fulfil the higher grede requirements
3.0 verification indicates that the student in most test cases identifies those cases in which the classical kinetics approach is not appropriate and does not fulfil the higher grede requirements
2.0: verification indicates that the student does not identifies those cases in which the classical kinetics approach is not appropriate and does not fulfil the higher grede requirements
EK2:
5.0: verification indicates that the student without noticeable imperfections select the best approach to solve problems related to chemical kinetics
4.5: verification indicates that the student almost correctly select the best approach to solve problems related to chemical kinetics and does not fulfil the higher grede requirements
4.0: verification indicates that the student substentially select the best approach to solve problems related to chemical kinetics and does not fulfil the higher grede requirements
3.5: verification indicates that the student substentially but inconsitently select the best approach to solve problems related to chem ical kinetics and does not fulfil the higher grede requirements
3.0: verification indicates that the student in most test cases select the best approach to solve problems related to chemical kinetics and does not fulfil the higher grede requirements
2.0: verification indicates that the student does not select the best approach to solve problems related to chemical kinetics and does not fulfil the higher grede requirements
Bibliography
CALDIN, Edward. The mechanisms of fast reactions in solution. Ios Press, 2001.
LAIDLER, Keith J. Chemical Kinetics. Prentice Hall; 3rd Revised edition, 1987.
RICE, Stuart A. Diffusion-Limited Reactions. Elsevier, 1985.
NITZAN, Abraham. Chemical Dynamics in Condensed Phases: Relaxation, Transfer and Reactions in Condensed Molecular Systems. Oxford University Press, 2006
GRZYBOWSKI, Bartosz A. Chemistry in motion: reaction-diffusion systems for micro-and nanotechnology. John Wiley & Sons, 2009.
Additional information
Additional information (registration calendar, class conductors, localization and schedules of classes), might be available in the USOSweb system: