Subjects

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Molecular modelling - M320043

Title:	Molekulové modelování
Guaranteed by:	Department of Biochemistry and Microbiology (320)
Faculty:	Faculty of Food and Biochemical Technology
Actual:	from 2023
Semester:	winter
Points:	winter s.:3
E-Credits:	winter s.:3
Examination process:	winter s.:
Hours per week, examination:	winter s.:2/0, Ex [HT]
Capacity:	unlimited / unknown (unknown)
Min. number of students:	unlimited
Language:	Czech
Teaching methods:	full-time
Teaching methods:	full-time
Level:
For type:	Master's (post-Bachelor)

Guarantor:	Spiwok Vojtěch prof. Ing. Ph.D. Raich Ivan doc. Dr. Ing.
Interchangeability :	N320095

Examination dates

This subject contains the following additional online materials

E-learning course

Annotation -

The subject covers theoretical backgrounds and practical examples of application of computational methods on molecular systems, namely molecular mechanics and quantum mechanics. It includes small molecules, as well as biomolecules and supra-molecular systems.

Last update: Kubová Petra (15.01.2018)

Aim of the course -

Students will be able to:

design, apply and analyse results of molecular modelling calculations (molecular mechanics, basic quantum chemistry methods, docking).

Last update: Kubová Petra (15.01.2018)

Literature -

R: D.C. Young: Computational Chemistry: A Practical Guide for Applying Techniques to Real World Problems. John Wiley & Sons, Inc., 2002, ISBN: 9780471333685 (print), 9780471220657 (online)

Last update: Kubová Petra (15.01.2018)

Learning resources -

https://web.vscht.cz/spiwokv/molmod/

https://web.vscht.cz/~spiwokv/modelovani2/

Last update: Spiwok Vojtěch (18.12.2023)

Requirements to the exam - Czech

Předmět je zakončen ústní zkouškou

Last update: Lipovová Petra (09.08.2023)

Syllabus -

1. 3D geometry, Cartesian coordinates, Z-matix, connectivity, PDB file

2. Inspection of 3D models, bond lengths, angles, torsions, rendering

3. Structure-potential energy relationship, different levels of theory, potential energy hypersurface

4. Molecular mechanics, ball-spring model, single point calculations

5. Schrödinger equation, wave function, approximative solutions, methods (including semi-empirical), variational methods, basis sets

6. Prediction of properties (charges, reaction kinetics and mechanisms, spectral and chiroptical properties)

7. Geometry optimization, local minima problem

8. Molecular vibrations, normal modes

9. Solvation, implicit and explicit solvent, continuum electrostatics

10. Molecular dynamics, PBC, NPT, NVT, thermostats, constraints

11. Sampling, data collection, analysis and visualisation

12. Mesoscopic simulations (coarse graining, Brownian simulations)

13. Free energy, metadynamics and related methods

14. Example studies

Last update: Kubová Petra (15.01.2018)

Registration requirements -

Physical Chemistry

Last update: Kubová Petra (15.01.2018)

Teaching methods
	Activity	Credits	Hours
	Konzultace s vyučujícími	0.5	14
	Účast na přednáškách	1	28
	Příprava na přednášky, semináře, laboratoře, exkurzi nebo praxi	0.5	14
	Příprava na zkoušku a její absolvování	1	28
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