Course No:11120870
Title:Optical Spectroscopy and Applications
Class Hours/Week: 1.5 - 1 Credit:2
Category:Elective
Prerequisites: Physical Optics
Audience:Undergraduate students
Teaching manner:Multimedia teaching
Course objectives and basic requirements:
The aim of this course is to provide undergraduate students with an introduction of modern optical spectroscopy and its applications in a variety of topics. Main content includes luminescence mechanism, detection techniques and equipment, as well as related applications. The course requires that the students to gain a comprehensive understanding of spectroscopy technology including operation principle, detection equipment and applications in ranges of IR, Raman, NMR and X-ray.
Course introduction:
This course mainly describes interactions between electromagnetic wave at different frequencies and materials, and uses the interaction characteristics to detect the compositions, structures and morphologies of the materials. The main content includes: (1) Guide of spectroscopy; (2) Analysis of spectra; (3) Technology of optical measurement; (4) Spectra of the nucleus-magnetism resonance;(5) Analysis of X-ray spectra.
Syllabus and lecture schedule:
Chapter 1. Guide of spectroscopy. 2 class hours
Basic properties of the electromagnetic waves 1 class hour
Summary of optical analysis of materials 1 class hour
Chapter 2. Spectroscopic analysis 8 class hours
The classification of spectra 1 class hour
Width and shape of spectrum 1 class hour
Spectroscopic analysis of fluorescence 1 class hour
Spectroscopic analysis of infrared ray 2 class hours
Spectroscopic analysis of laser scattering Raman 1 class hour
General method of spectral analysis 2 class hours
Chapter 3. Technology and application of optical measurement 6 class hours
Spectrum of time differentiate 2 class hours
Polarized spectrum and fine spectrum 2 class hours
Pumping and detecting 2 class hours
Chapter 4. Spectrum of the nucleus-magnetism resonance 4 class hours
Introduction of the general mechanism 1 class hours
Imaging mechanism of NMR 2 class hours
Applications and development 1 class hours
Chapter 5. Analysis of X-ray 4 class hours
Introduction 1 class hours
Interaction of X-ray with substances 1 class hours
Mechanism of the X-Ray diffraction 1 class hours
Imaging and detecting of X-Ray 1 class hours
Related teaching sections:
A number of experiments will be arranged for 8 hours after Chapter 2; and one experiment for 4 hours after Chapter 4 and Chapter 5 respectively. (Referred to Lab Manuel)
Test and Grading Criteria:
Open-book Exam
Suggested textbooks or references:
1. Guowen Wang. Guide of Atom and Molecule Spectrum. Bejing; Publisher of Beijing University, 1985
2. Kone. Atom spectroscopy and Molecule spectroscopy. Beijing, Science Publisher, 1984
3.Tiejun Chang. Modern Analysis and measurement methods of Materials. Publisher of University of Haerbin Technology 2000
4. Gang Wu. Characterizations and applications of material structure. Publisher of Chemical Industry,2001
2. Kone. Atom spectroscopy and Molecule spectroscopy. Beijing, Science Publisher, 1984
3.Tiejun Chang. Modern Analysis and measurement methods of Materials. Publisher of University of Haerbin Technology 2000
4. Gang Wu. Characterizations and applications of material structure. Publisher of Chemical Industry,2001