Faculty of Science

Model (No 12)

Course Specification : تحليل طيفى - ضوء فيزيائى

2010 - 2011

 
Farabi Quality Management of Education and Learning - 22/12/2024
University :Mansoura University
Faculty :Faculty of Science
Department :Physics Department
1- Course data :-
Code: 40204
Course title: تحليل طيفى - ضوء فيزيائى
Year/Level: ثانية بيولوجى
Program Title:
  • Zoology
Specialization:
Teaching Hours: Theoretical: 4Tutorial: Practical: 4
2- Course aims :-
  1. Introduce the student to the concept of the wave nature of light.
  2. Acquaint the student with the fact that the superposition of light waves leads to a wide variety of effects called interference.
  3. Study two beams and multiple beam interference and application.
  4. Acquire the student’s skills to drive mathematical formula of the diffraction of light.
  5. Enable the students to use the diffraction grating as a powerful device for dispersing lightinto its component wavelength.
  6. Study the polarization is firm evidence of the transverse nature of light wave.
  7. Introduce the students a comprehensive picture of the physical phenomena occurring in the atoms when being excited.
  8. Study how spectrum is emitted or absorbed.
  9. Introduce relation between atomic structure & atomic spectrum.
  10. Study importance of spectroscopic analysis methods and their high sensitivity &accuracy.
  11. Introduce the students to the basic fundamentals of "Spectroscopy" including its different types, regions, importance, etc… and emphasizing the concepts of energy levels, electronic transition, atomic excitation & ionization .
3- Course Learning Outcomes :-
4- Course contents :-
NoTopicsWeek
1Physical optics :wave motion: Path difference, energy of vibrating particle, superposition of two wave
2Interference of two beam of light: 1- division of wave front & 2-division of amplitude.
3Interference of multiple beam
4Diffraction of light
5Polarization of light
6spectra analysis : General introduction about atomic & molecular spectroscopy. Characterization of the EMR and the E.M. Spectrum regions. Quantization of energy and energy levels. Definition of terms. Elements of atomic theory, Hydrogen atom, Bohr theory, Sommerfield’s refinements, Lorentz formula.
7Fine & hyperfine structure, line splitting, selection rules, electron spin, Pauli Excln. many elecn. spc. Zeeman effect, Paschen-Back effect, periodic table, Hyperfine structure& Nuclear spin, Isotopic effect
8Basics of practical spectroscopy, atomic emission methods, related spectral terms, instrumentation. Excitation sources; flame, d.c.arc, a.c.arc, a.c. spark; discharge tubes; hollow cathode, atomic beams & Lasers.
9Monochromators; prisms and diffraction gratings. Detectors; photographic & photoelectric.
10Qualitative & quantitative spectroscopic analysis.

5- Teaching and learning methods :-
SMethod
Lectures using over hed projector and board
Discussion sessions
Problem classes and group tutorial
Class activity.
Laboratory work

6- Teaching and learning methods of disables :-
  1. The same as normal students, only skeletal disabilities are allowed in the Faculty of Science.

7- Student assessment :-
A. Timing
NoMethodWeek
1final exam14
2oral exam14
3practical exam13
4report8
B. Degree
NoMethodDegree
1Mid_term examination0
2Final_term examination70
3Oral examination 10
4Practical examination 20
5Semester work0
6Other types of asessment0
Total100%

8- List of books and references
SItemType
1Notes offered by the department
26.2 - Physics for Scientists and Engineers Raymond A. Serway, John W. Jewett 6th Edition, 2004
36.3 - Physics, Sixth edition, By: Hallidy, Resnick and Krane. John Wiely & 2003

9- Matrix of knowledge and skills of the course
SContentStudy week
Physical optics :wave motion: Path difference, energy of vibrating particle, superposition of two wave
Interference of two beam of light: 1- division of wave front & 2-division of amplitude.
Interference of multiple beam
Diffraction of light
Polarization of light
spectra analysis : General introduction about atomic & molecular spectroscopy. Characterization of the EMR and the E.M. Spectrum regions. Quantization of energy and energy levels. Definition of terms. Elements of atomic theory, Hydrogen atom, Bohr theory, Sommerfield’s refinements, Lorentz formula.
Fine & hyperfine structure, line splitting, selection rules, electron spin, Pauli Excln. many elecn. spc. Zeeman effect, Paschen-Back effect, periodic table, Hyperfine structure& Nuclear spin, Isotopic effect
Basics of practical spectroscopy, atomic emission methods, related spectral terms, instrumentation. Excitation sources; flame, d.c.arc, a.c.arc, a.c. spark; discharge tubes; hollow cathode, atomic beams & Lasers.
Monochromators; prisms and diffraction gratings. Detectors; photographic & photoelectric.
Qualitative & quantitative spectroscopic analysis.

Course Coordinator(s): -
  1. Mohamed Mohamed Mansour Gabr
Head of department: -
Mohamed Abd Elqader Hassan Madkor