Atomic and Molecular Spectroscopy (Theory)

Paper Code: 
24CPHY412
Credits: 
04
Contact Hours: 
60.00
Max. Marks: 
100.00
Objective: 
Course Objectives: 
This course will enable the students to- 
Get idea about various types of spectra for hydrogen, alkali and alkaline earth atoms. It also gives an introduction to X-ray spectra. Techniques of Molecular spectroscopy are also discussed in this paper, which include IR and Raman spectra. 
develop capabilities of making spectroscopic analysis of materials and draw conclusions from the same regarding nature of material.
 
Course Outcomes: 

Course Outcomes (COs):

 

Course

Learning outcome

(at course level)

Learning and teaching strategies

Assessment Strategies

Course Code

Course Title

 

 

 

24CPHY412

Atomic and Molecular Spectroscopy

(Theory)

 

CO67: Differentiate different types of spectra, explanation of  Hydrogen spectra and applications of Stern-Gerlach experiment

CO68:    Discuss alkali metal and alkaline earth metal spectra.

CO69: Demonstrate and explain  X-Ray spectra.

CO70: Gain knowledge of the salient features of IR spectra and its experimental arrangements.

CO71: Apply the results of Raman spectra to determine the structure of molecules.

CO72: Contribute effectively in course - specific interaction

Approach in teaching:

Interactive Lectures, Discussion, Tutorials, Power point presentation,  Problem Solving in tutorials

Learning activities for the students:

Self learning assignments, Effective questions, Seminar presentation, Solving numericals

Class test, Semester end examinations, Quiz, Solving problems, Assignments, Presentations

 

 

 

12.00
Unit I: 
Introduction to Atomic Spectra:

Types of spectra, spectrum of Hydrogen atom, spectral lines, the spinning electron, space quantization, quantum numbers and their physical interpretation, quantum numbers for complete atom, magnetic moments of an atom and Landes ‘g’ factor, Larmor’s theorem, Stern and Gerlach experiment, fine structure of the Hydrogen lines, spectral terms and their notation.

12.00
Unit II: 
Spectra of alkali and alkaline atoms:

Different series in alkali spectra, Ritz combination formula, spin orbit interaction, explanation of salient features of alkali spectra, doublet structure in alkali spectra (fine structure), Transition rules, intensity rules, spectra of alkaline earth metals, coupling schemes: L.S and j-j coupling, selection rules in atoms of two valence electrons, singlet and triplet series, spectrum of Helium atom.

12.00
Unit III: 
X-ray Spectra:

Continuous x-ray spectrum, characteristic emission and absorption spectrum and their explanation, energy levels, Moseley’s law, combination principle, fine structure of x-ray lines, fluorescence yield and Auger effect, soft x-ray emission and structure of absorption edges.

12.00
Unit IV: 
Infra-red spectroscopy (vibrational and rotational spectra):

Salient features of vibrational rotational spectra, vibrating diatomic molecules as a harmonic oscillator, fine structure of vibrational rotational bands, interaction of vibrational and rotational energies, experimental arrangements for studying IR spectra.

12.00
Unit V: 
Raman Spectra:
Raman effect and its salient features, Observation of Raman spectra, classical theory of Raman effect, quantum theory of Raman effect, probability of energy transition in Raman effect, vibrational Raman spectra, Pure rotational Raman spectra, structure determination from Raman and infra red spectroscopy.
 
Essential Readings: 
“Elements of Spectroscopy”, Gupta, Kumar, Sharma, Pragati Prakashan, 2006.
“Fundamentals of molecular spectroscopy”, Collin N. Banwell and Elaine M. McCash, Tata McGraw Hill Publishing Company Ltd. New Delhi, 2005.
References: 
“Introduction to Atomic Physics”, Enge, Wehr and Richards, Addison Wiesley, London.
“Atomic and Nuclear Physics”, A.B. Gupta, New Central book agency Pvt. Ltd.
“Atomic Spectra and Atomic structure”, Gerhard Herzberg , Kreiger Pub.Co.,Second Edition.
“Molecular Spectra and Molecular structure: Spectra of diatomic Molecules”, Gerhard Herzberg, Dover Publications.
 
 
E-Content:
 
 
Academic Year: 
2024-2025
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