Course Syllabus
Titolo
Introduction to photochemistry
Docente(i)
Luca Bertini ; Federica Arrigoni; Claudio Greco ; Antonio Papagni
Lingua
English
Breve descrizione
The basic principles of Photophysics and photochemistry applied to photocatalisys
- Unimolecular and bimolecular excited state decay processes
- Dyad photosensitizer-catalist in pohotocatalysis
- Photoinduced Electron transfer: Markus theory and quantum approach
- Energy transfer: Förster and Dexter mechanism
- All-in-one example: [Ru(bpy)₃]²⁺ in electron-trasfer and energy transfer photocatalysis
- How to investigate photocatalytic processes: experimental tecniques (absorption and emission spectroscopies, photochemical kinetic measurement within Stern-Volmer equation) and computational approches (Time-dependent DFT)
Photophysics:
- light-matter interaction and photostimulation processes
- Interactions between atoms and molecules and photographic processes
- Frank-Condon's Principle
- Dynamics and time scale for decaying an excited state (fluorescence, phosphorescence)
Photochemistry:
- Organic photochemistry and photochemical processes
- Organic photochemistry: Photostimulate organic reactions
- Radical or ionic dissociation
- Intrameloogic rearrangements and photoisomers
- Hydrogen atom abstraction
- Photodimerization, photoaddition, photoionisation reactions
- Photochemical activity of aromatic compounds
- photochemistry of diazo- and azide compounds
- Photo-removable protective groups
- Chemiluminescence
Technical and experimental aspects of organic photochemistry
- Inorganic photochemistry and coordination compounds
- Characterization of the inorganic and coordinated electron spectra
- Decay and Lifetime kinetics of an excited state
- Energy transfer: Förster and Dexter mechanism
- Electron transfer: Markus theory and quantum approach
- Proton-coupled electron transfer
- Redox properties of excited states of coordination compounds: the case of [Ru(bpy)3]2+;
Objective of the program: The mini-course of photochemistry is an introduction to a selection of general, organic, inorganic, biological, solid state and theoretical photochemical themes with the aim of providing to phd students knowledge in basic principles and application of photochemistry.
Evaluation: NO
CFU / Ore
3 CFU - 24 Hours (Lecture)
Periodo di erogazione
II semester: from 2nd half of May till the end of July 2024
Title
Introduction to photochemistry
Teacher(s)
Luca Bertini ; Federica Arrigoni; Claudio Greco ; Antonio Papagni
Language
English
Short description
The basic principles of Photophysics and photochemistry applied to photocatalisys
- Unimolecular and bimolecular excited state decay processes
- Dyad photosensitizer-catalist in pohotocatalysis
- Photoinduced Electron transfer: Markus theory and quantum approach
- Energy transfer: Förster and Dexter mechanism
- All-in-one example: [Ru(bpy)₃]²⁺ in electron-trasfer and energy transfer photocatalysis
- How to investigate photocatalytic processes: experimental tecniques (absorption and emission spectroscopies, photochemical kinetic measurement within Stern-Volmer equation) and computational approches (Time-dependent DFT)
Photophysics:
- light-matter interaction and photostimulation processes
- Interactions between atoms and molecules and photographic processes
- Frank-Condon's Principle
- Dynamics and time scale for decaying an excited state (fluorescence, phosphorescence)
Photochemistry:
- Organic photochemistry and photochemical processes
- Organic photochemistry: Photostimulate organic reactions
- Radical or ionic dissociation
- Intrameloogic rearrangements and photoisomers
- Hydrogen atom abstraction
- Photodimerization, photoaddition, photoionisation reactions
- Photochemical activity of aromatic compounds
- photochemistry of diazo- and azide compounds
- Photo-removable protective groups
- Chemiluminescence
Technical and experimental aspects of organic photochemistry
- Inorganic photochemistry and coordination compounds
- Characterization of the inorganic and coordinated electron spectra
- Decay and Lifetime kinetics of an excited state
- Energy transfer: Förster and Dexter mechanism
- Electron transfer: Markus theory and quantum approach
- Proton-coupled electron transfer
- Redox properties of excited states of coordination compounds: the case of [Ru(bpy)3]2+;
Objective of the program: The mini-course of photochemistry is an introduction to a selection of general, organic, inorganic, biological, solid state and theoretical photochemical themes with the aim of providing to phd students knowledge in basic principles and application of photochemistry.
Evaluation: NO
CFU / Hours
3 CFU - 24 Hours (Lecture)
Teaching period
II semester: from 2nd half of May till the end of July 2024