Lecture Solid State Spectroscopy
Lecturers: Mohammad Mangir Murshed
(1) Basics for spectroscopy
Electromagnetic radiation, Black-body radiation, Maxell’s theory, Hertzian dipole, periodic function, Dirac-delta function, Gaussian, Lorentzian, convolution, auto-correlation, Fourier transform, distribution function, wavevector, de-Broglie particle
(2) Raman spectroscopy
Harmonic oscillator, Maxwell-Boltzmann distribution law, polarizability tensor and origin of Raman effect, Stokes and anti-Stokes, symmetry and selection rules, depolarization ratio, instrumentation and experiments, temperature/pressure-dependent Raman, phonon decay.
(3) Infrared spectroscopy:
IR activity, dipole induced radiation, interferometers, interferograms, fundamentals, overtones and combinations, Fermi resonance, Darling-Dennison resonance, transmission FTIR, DRIFTS, ATR, FIR, MIR, NIR, usages of FTIR.
(4) UV-Vis spectroscopy:
Band structure, electronic transition, direct and indirect bandgaps, Franck-Condon effect, absorption, reflectance, Kramers-Kronig relations, Kubelka-Monk approximation, Tauc’s method, DASF method, size- and temperature-dependent bandgaps.
(5) Solid state NMR:
Nuclear spin, Boltzmann distribution, gyromagnetic ratio, Zeeman effect, Larmor frequency, MAS NMR, chemical shift anisotropy, MAS NMR of quadrupolar nuclei, MQ-MAS NMR.
6) Neutron spectroscopy:
Optical silent modes and other limitations at in-house facilities, neutron sources and detection, neutron cross-section, inelastic and quasi-elastic neutron scatterings, coherent and incoherent neutron scatterings, phonon dispersion, phonon density of states.
7) X-ray and electron spectroscopy:
Introduction to Resonant Inelastic X-ray scattering (RIXS), Extended X-ray Absorption Fine Structure (EXAFS), and Electron Energy Loss Spectroscopy (EELS)
After attending the course the participants shall have the following skills:
- know and properly use basic terminology of solid state spectroscopy, and its applications
- know how to meet the complementary spectroscopic technique to resolve a bulk/local physico-chemical phenomena of a given condensed matter- know how to correlate the spectral information to the bulk analysis such as X-ray/neutron elastic scatting.
written exam
Klausur
Hans Kuzmany: Solid-State Spectroscopy: An Introduction (Springer, Heidelberg, 2nd Edition, 2009)
Norman B. Colthup, Lawrence H. Daly, Stephen E. Wiberley: Introduction to Raman and Infrared Spectroscopy (Academic Press, San Diego, 1990)
Heinz-Helmut Perkampus: UV-VIS Spectroscopy and Its Applications (Springer, Heidelberg1992)
Melinda J. Duer: Introduction to Solid-State NMR Spectroscopy (Blackwell, Oxford, 2005)
Françoise Hippert, Erik Geissler, Jean Louis Hodeau, Eddy Lelièvre-Berna, Jean-René Regnard: Neutron and X-ray Spectroscopy (Springer, Berlin, 2006)
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Basic Data
05-MCM-SO-1
Study Program
Master Materials Chemistry and Mineralogy
Module Name
Solid State Spectroscopy
Course Type
Lecture (L)
First Year of Study
3 CP
2 SWS
Summer Term
Course Language
English