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Course Catalog 2014-2015
FYS-2306 Electron Spectroscopy, 5 cr |
Additional information
Suitable for postgraduate studies
Person responsible
Mika Valden
Lessons
Study type | P1 | P2 | P3 | P4 | Summer | Implementations | Lecture times and places |
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Requirements
Passed learning assignments.
Completion parts must belong to the same implementation
Learning Outcomes
After completing the course, the student will be able to define the physical operation principles of electron spectroscopy methods such as XPS, AES, ARUPS and NEXAFS. The student will learn how to apply the electron spectroscopy methods to identify elemental distribution of solid surfaces, nanostructures and molecular structure of surface compounds. During the course, the student will learn to solve surface analytic research problems in tutorial learning sessions (groups of 4-6 students) based on the shared expertise of the group members. The student will master the skills required to report the results of the learning assignments using Moodle learning management system as well as in the forms of a research report and a seminar presentation.
Content
Content | Core content | Complementary knowledge | Specialist knowledge |
1. | Surface analysis and surface sensitivity: Principles of surface analytical research. Surface sensitivity. Application examples of surface analysis. | Surface science research at TUT. | |
2. | Vacuum technique: Definition of vacuum. Vacuum ranges. Residual gas. Vacuum pumps. Pressure measurements. Vacuum compatible materials. | Rotary vane pump. Diffusion pump. Turbomolecular pump. Sorption pump. Titanium sublimation pump. Ion pump. Mass spectrometer. | Vacuum environments. |
3. | Electron Spectroscopy: Classification of electron spectroscopy methods. Attenuation length and information depth. Energy analysers. | Historical perspectives of electron spectroscopy. Role of emission angle to information depth. Retarding field analysers. Mirror plane analyser. Concentric Hemispherical Analyser. | Electrical derivation. |
4. | X-ray photoelectron spectroscopy (XPS): Photon sources. Spectral features and chemical shifts. Adiabatic approximation. Nanostructures on surfaces. XPS as an analytical method. | X-ray lines and X-ray satellites. Three-step model of photoemission. Koopman's theorem. Analysis of the extrinsic electron energy loss structure. Quantitative analysis. | Intrinsic and extrinsic processes of photoemission. Many-electron effects in photoemission. |
5. | Auger electron spectroscopy (AES): Auger-transition. Energy of the Auger transition. AES as an analytical method. Comparison of XPS and AES methods. Depth profiling. | X-ray fluorescence yield versus Auger electron yield. | Carbon KVV-transition. |
6. | Ultra-violet photoemission spectroscopy (UPS): Photon sources and surface sensitivity of UPS. Orientation and symmetry of adsorbed molecules. Surface molecule point groups. Polarization-dependent selection rules. | Fermi's Golden Rule. Dipole matrix element. Character table. Polarization. ARUPS CO/Ni(100). | Hûckel molecular orbital theory. ARUPS C6H6/Pd(110). |
7. | X-ray absorption spectroscopy (XAS): Synchrotron radiation and surface science. NEXAFS and EXAFS methods. | Analysis of EXAFS spectrum. | XAS of Cu oxides. |
Instructions for students on how to achieve the learning outcomes
The assessment of the course is either numeric on the grade scale of 0 ... 5 or "Pass/Fail". The assessment method will be decided together with the students at the beginning of the course. The numeric assessment is based on a literature exam. If the student demonstrates thorough understanding of the core content, s/he may pass the course with the grade 3. In order to achieve grade 4, the student must also demonstrate competency in the points specified in column "Complementary knowledge". The student may achieve grade 5, if s/he demonstrates good command of the points specified in column "Specialist knowledge". If there are minor shortcomings regarding the core content, the student may receive the grade 1 or 2, depending on the number of flaws. If there are significant shortcomings regarding core content, the student will not pass the course. The assessment of the course can also be "Pass/Fail". The student can earn the passing grade, if s/he has completed all the learning assignments in a satisfactory manner.
Assessment scale:
Numerical evaluation scale (1-5) will be used on the course
Partial passing:
Study material
Type | Name | Author | ISBN | URL | Edition, availability, ... | Examination material | Language |
Book | Surface Analysis by Auger and X-ray Photoelectron Spectroscopy | Briggs, D. and Grant ,J.T | 1 901019 04 7 | IM Publications and SurfaceSpectra Limited, 1. edition, 2003 | Yes | English | |
Lecture slides | Valden Mika | Yes | English |
Prerequisite relations (Requires logging in to POP)
Correspondence of content
Course | Corresponds course | Description |
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More precise information per implementation
Implementation | Description | Methods of instruction | Implementation |