Detail předmětu

Photochemistry

FCH-MA_FCPAk. rok: 2023/2024

Fundamental principles, structure of electronic excited states, electronic absorption spectra, static and dynamic properties of excited states, Jablonski diagram and transitions between electronic excited states, kinetics of photophysical and photochemical processes. Sources of UV radiation. Basics of photochemical reactions, photocatalytic reactions. Imaging systems, photochemical imaging systems (light sensitive polymers, others), UV curing technology and systems, electrophotography, photodegradation and photostabilization of polymer materials, environmental photochemical processes and technologies.

Jazyk výuky

angličtina

Počet kreditů

4

Nabízen zahraničním studentům

Pouze domovské fakulty

Pravidla hodnocení a ukončení předmětu

oral exam

Učební cíle

To provide an overview of the concepts of photochemistry as a scientific discipline and their application potential.
Theoretical background of photochemistry and photophysics, photochemical reactions of organic, inorganic and macromolecular compounds, polymer imaging systems and photopolymerizable systems and their use, photodegradation and photostabilisation of polymer materials, background of photochemical reactions in atmosphere.

Základní literatura

Brian Wardle: Principles and Applications of Photochemistry, Wiley 2009 (EN)

Elearning

Zařazení předmětu ve studijních plánech

  • Program NPCP_CHCHTE magisterský navazující 1 ročník, zimní semestr, povinný
  • Program NKCP_CHCHTE magisterský navazující 1 ročník, zimní semestr, povinný
  • Program NPAP_ENVI magisterský navazující 1 ročník, zimní semestr, povinný

Typ (způsob) výuky

 

Konzultace v kombinovaném studiu

26 hod., nepovinná

Vyučující / Lektor

Přednáška

26 hod., nepovinná

Vyučující / Lektor

Osnova

1 Introductory Concepts
1.1 The quantum nature of matter and light
1.2 Modelling atoms: atomic orbitals
1.3 Modelling molecules: molecular orbitals
1.4 Modelling molecules: electronic states
1.5 Light sources used in photochemistry (mercury lamp and lasers)
1.6 Efficiency of photochemical processes: quantum yield
2 Light Absorption and Electronically-excited States
2.1 The Beer-Lambert law
2.2 The physical basis of light absorption by molecules
2.3 Absorption of light by organic molecules
3 The Physical Deactivation of Excited States
3.1 Jablonski diagrams
3.2 Excited-state lifetimes
4 Radiative Processes of Excited States
4.1 Fluorescence and fluorescence spectra
4.2 Fluorescence quantum yield
4.3 Molecular fluorescence in analytical chemistry
4.4 Phosphorescence
4.5 Delayed fluorescence
4.6 Lanthanide luminescence
5 Intramolecular Radiationless Transitions of Excited States
5.1 The energy gap law
5.2 The Franck-Condon factor
5.3 Selection rules for intersystem crossing
6 Intermolecular Physical Processes of Excited States
6.1 Quenching Processes
7 Investigating Some Aspects of Photochemical Reaction Mechanisms
7.1 Information from electronic spectra
7.2 Triplet-quenching studies
7.3 Sensitisation
8 Semiconductor Photochemistry
8.1 Solar energy conversion by photovoltaic cells
8.2 Semiconductors as sensitisers for water splitting
8.3 Semiconductor photocatalysis
8.4 Semiconductor – photoinduced superhydrophilicity
9 Imaging systems, photochemical imaging systems
9.1 Photoresists
9.2 UV curing technology

Elearning