Description of Individual Course Units
Course Unit CodeCourse Unit TitleType of Course UnitYear of StudySemesterNumber of ECTS Credits
9101045632005Molecular SpectroscopyElective118
Level of Course Unit
Second Cycle
Objectives of the Course
The aim of this course is to teach the basic concepts of spectroscopy.
Name of Lecturer(s)
Prof. Dr. Nadide KAZANCI
Learning Outcomes
1Being able to comprehend the interactions between electromagnetic radiation with matter.
2Being able to learn various spectroscopic techniques.
3Being able to evaluate analysis types of these techniques.
4Being able to comprehend the applicability of these techniques in the field of science.
Mode of Delivery
Face to Face
Prerequisites and co-requisities
None
Recommended Optional Programme Components
None
Course Contents
Basic Concepts in Spectroscopy, Principles and Applications of UV-Vis Spectroscopy, Infrared Spectroscopy, Raman Spectroscopy, NMR Spectroscopy and Applications, Mass Spectroscopy, ESR Spectroscopy, Electronic Applications in Spectroscopy
Weekly Detailed Course Contents
WeekTheoreticalPracticeLaboratory
1Definition of spectroscopy, Properties of Electromagnetic Radiation, Wave Characteristics of Radiation, Interference and Diffraction
2Particle Characteristics of Radiation, Eletromanyetic Spectrum, Quantitative Structure of Matter and Transitions, Energy Levels and Transitions
3Energy Distribution of Many Atom or Molecule, Interaction of Radiation with Matter, Selectivity Rules for Some Systems
4Basic Terms and Definitions, Radiation and Matter Interactions, Atomic and Molecular Energy Transitions, Absorption Event and Absorption Types
5Devices Measuring UV and Visible Absorbtion, Qualitative Analysis, Quantitative Analysis, Areas Outstanding Benefits of UV - Visible Absorption Spectroscopy
6Infrared Theory, Types of Vibration and Selectivity Rules, Factors Affecting Group Frequencies, Infrared Spectrophotometer
7Sample Preparation and Measurement Technique, Applications of Infrared Spectroscopy, Structure Determination, Raman Theory
8Midterm exam
9Raman Spectrometers, Applications of Raman Spectroscopy, Angular Momentum and Magnetic Momentum, NMR Cores
10Larmor Precession and Nuclear Magnetic Resonance, Relaxation, NMR Signal Intensity
11Local Magnetic Fields and Clear Area Acting on Core, Spin Systems
12Mass Spectrometer Parts, Separation Force, Peak Ratios Account in Spectrum using Isotopes, Evaluation of Mass Spectra, Solution Method of Mass Spectrum
13Electron Spin Resonance, Interaction Electron-Nuclear Hyperfine Structure, Spin Hamiltonien, Experimental Determination of g Tensor
14Hyperfine Structure Tensor, Electron spin resonance Methods to Obtain Information, Examples of Electron Spin Resonance Spectra
15What is Electricity?, Electron Current, Electromotive Force, Conductivity and Resistance, Ohm's Law, Capacitance, What is the circuit?, Circuit Connections, Semiconductors, Integrated Circuit
16Final exam
Recommended or Required Reading
Iaın D.Campbell, Raymond A. Dwek, 1994, Biological Spectrsocopy, Benjamin/Cumming Publishing Company
Planned Learning Activities and Teaching Methods
Assessment Methods and Criteria
Term (or Year) Learning ActivitiesQuantityWeight
SUM0
End Of Term (or Year) Learning ActivitiesQuantityWeight
SUM0
SUM0
Language of Instruction
Turkish
Work Placement(s)
None
Workload Calculation
ActivitiesNumberTime (hours)Total Work Load (hours)
Midterm Examination122
Final Examination122
Attending Lectures14342
Project Preparation23060
Project Presentation212
Individual Study for Mid term Examination16060
Individual Study for Final Examination17070
TOTAL WORKLOAD (hours)238
Contribution of Learning Outcomes to Programme Outcomes
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1
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2
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3
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4
PO
5
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6
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7
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8
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9
PO
10
PO
11
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LO243343334335
LO344343334333
LO454343354435
* Contribution Level : 1 Very low 2 Low 3 Medium 4 High 5 Very High
 
Ege University, Bornova - İzmir / TURKEY • Phone: +90 232 311 10 10 • e-mail: intrec@mail.ege.edu.tr