MOLECULAR SPECTROSCOPY PART B

Degree course: 
Corso di Second cycle degree in CHEMISTRY
Academic year when starting the degree: 
2023/2024
Year: 
2
Academic year in which the course will be held: 
2024/2025
Course type: 
Supplementary compulsory subjects
Credits: 
4
Period: 
First Semester
Standard lectures hours: 
32
Detail of lecture’s hours: 
Lesson (32 hours)
Requirements: 

Quantum Mechanics is a standard prerequisite for this course.

Oral examination on both part A and B of the course (30 min). Four questions:
2 questions on the content of section 1 as in the course program.
2 questions on the content of sections 2-7 as in the course program.

The evaluation criteria will consider:
1) the completeness of the acquired knowledge.
2) ability to report critically about the advantages and limitations of the different techniques.
3) ability to indicate the more appropriate spectroscopy to be used in different scenarios.
4) the technical terminology used.

Assessment: 
Voto Finale

• Knowledge and understanding
o the regions of the electromagnetic spectrum
o the main spectroscopic techniques
o spectroscopic transition rules
• Skills aims.
o Bottom-up approach to chemical problems
o Extraction of the information from an experiment using a coherent physical model
o Selection of the most suitable technique(s) according to the desired outcome
o Critical analysis of experimental results
• Communicative aims
o This lesson aims at helping learners become better able to explain the logic process that brings to the selection of a spectroscopic techniques.
• Autonomous assessment
o Selection of the spectroscopic approach
o Discussion of results

4. Electronic spectroscopy (8 h).
4.1. Atomic spectra and classification of electronic states. Electronic states and spectra of diatomic molecules. Vibrational and rotational structure.
4.2. Polyatomic molecules and electronic states. Chromophores. Fate of the excited states.
4.3. Decay processes, fluorescence, and phosphorescence.
5. Laser and spectroscopy. Laser examples. Use of lasers in spectroscopy, e.g. raman spectroscopy and femtochemistry (4 h).
6. Photoelectron spectroscopy. (8 h)
6.1. Ionization processes and Koopmans theorem.
6.2. UPS, XPS, Auger spectroscopies.
6.3. Synchrotron radiation. XAS and XES spectroscopies.
7. Magnetic spectroscopies: principles and applications (8 h).
7.1. Nuclear magnetic resonance (NMR).
7.2. Electron paramagnetic resonance (EPR)
8. Mössbauer spectroscopy. (4 h)

4. Electronic spectroscopy (8 h).
4.1. Atomic spectra and classification of electronic states. Electronic states and spectra of diatomic molecules. Vibrational and rotational structure.
4.2. Polyatomic molecules and electronic states. Chromophores. Fate of the excited states.
4.3. Decay processes, fluorescence, and phosphorescence.
5. Laser and spectroscopy. Laser examples. Use of lasers in spectroscopy, e.g. raman spectroscopy and femtochemistry (4 h).
6. Photoelectron spectroscopy. (8 h)
6.1. Ionization processes and Koopmans theorem.
6.2. UPS, XPS, Auger spectroscopies.
6.3. Synchrotron radiation. XAS and XES spectroscopies.
7. Magnetic spectroscopies: principles and applications (8 h).
7.1. Nuclear magnetic resonance (NMR).
7.2. Electron paramagnetic resonance (EPR)
8. Mössbauer spectroscopy. (4 h)

Frontal lessons (32 hours): introduction and theoretical development of the topics, exemplified by means of typical cases.
During the lessons, students are often involved by means of questions to make them more engaged according to the basic principles of active learning in its most elementary way.
Part of the lessons will be dedicated to the analysis of literature spectra obtained through the different techniques seen in the course. The educational goal of the exercises is to provide practical tools for the analysis of spectra and, through discussion, to develop a modus cogitandi for students to assign a certain spectroscopic technique to the resolution of a problem.

Contacts/Info: Every day by email appointment.

Parent course