Course Objectives:
This course will enable the students to –
be aware about the principles and applications of rotational, vibrational, Raman, electronic and NMR spectroscopy techniques.
have the knowledge about various processes involved during interaction of radiation with matter.
Course Outcomes (COs):
Course |
Learning outcomes (at course level) |
Learning and teaching strategies |
Assessment Strategies |
|
Paper Code |
Paper Title |
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CHY 603 |
Spectroscopy and Photochemical Laws (Theory)
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The students will be able to –
CO106: discuss qualitative and quantitative knowledge of the fundamental concepts of spectroscopy. CO107: describe principle, selection rules and applications of rotational, vibrational, Raman, electronic and NMR spectroscopy. CO108: apply spectroscopic data for molecular characterization. CO109: outline fundamentals of photochemistry and laws governing it. CO110: evaluate the various deactivation processes of molecular excited states. |
Interactive Lectures
Explicit Teaching
Discussion
Didactic questions
Tutorials
Multimedia Presentations
Demonstration
Learning activities for the students:
Self learning Assignments
Peer Assessment
Concept mapping
Think/Pair/Share, Problem Solving, Power Point Presentation, Handouts |
The oral and written examinations (Scheduled and surprise tests)
Closed book and open book tests
Quiz
Problem solving exercises
Assignments
Presentation
Semester End Examinations |
Diatomic molecule, energy levels of a rigid rotor (semi-classical principles), selection rules, spectral intensity, distribution using population distribution (Maxwell-Boltzmann distribution), determination of bond length, qualitative description of non-rigid rotor, isotope effect, Born –Oppenheimer approximation.
Energy levels of simple harmonic oscillator, selection rules, pure vibrational spectrum, intensity, determination of force constant, qualitative relation of force constant and bond energies, effect of anharmonic motion and isotope on the spectrum, idea of vibrational frequencies of different functional groups,rotational- vibrational spectrum.
Raman spectrum: Concept of polarizability, pure rotational Raman and pure vibrational Raman spectra of diatomic molecules, selection rules.
Concept of potential energy curves for bonding and antibonding molecular orbitals, qualitative description of selection rules and Franck–Condon principle, qualitative description of s, p and n molecular orbitals, their energy levels and respective transitions.
Introduction, principle of nuclear magnetic resonance, nuclear shielding and deshielding, energies of nuclei in magnetic fields, technique, chemical shift, spin-spin coupling and coupling constant, proton spectra of simple compounds like ethanol, ethyl acetate, 1,2-dibromoethane.
Interaction of radiation with matter, difference between thermal and photochemical processes, laws of photochemistry: Grotthuss–Draper law, Stark-Einstein law, Jablonski diagram depicting various processes occurring in the excited state, qualitative description of fluorescence, phosphorescence, non-radiative processes (internal conversion, intersystem crossing); quantum yield, energy transfer processes – Photosensitization.