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Explanatory Notes
Instructions
Anotation:
Modern semiconductor devices and integrated circuits are based on unique energy band, carrier transport, and optical properties of semiconductor materials. Students will be prepared to choose these properties for operation of semiconductor devices. Emphasis is on quantum mechanical foundations of the properties of solids, energy bandgap engineering, semiconductor statistics, semi-classical transport theory (Boltzmann transport equation), carrier scattering, electro-magneto transport effects, high field ballistic transport, optical absorption, and radiative and non-radiative recombination. These princliples will be studied on the experimental basis as well. Students will prepare own structures according their thesis subjects and they will characterise them during their individual projects
Study targets:
To gain the theoretical knowledge and practical applications of modern technologies, nanostructures and material characterisation methods.
Content:
Introduction into theory of nanostructures and quantum based devices in electronics. Application of this knowledge in device design, preparation and characterisation in framework of individual projects in connection with the student's research work.
Course outlines:
| 1. | | Basic concepts. Electron and hole transport in semiconductor crystals |
| 2. | | Band structure, effective mass, mobility |
| 3. | | Boltzmann's transport equation. Scattering mechanisms, |
| 4. | | Scattering on phonons, ionised impurities, velocity saturation |
| 5. | | Relaxation time approximation |
| 6. | | Carrier transport in a strong electric field, velocity saturation |
| 7. | | Carrier transport in magnetic field, Quantum Hall effect |
| 8. | | Carrier transport in nanometre structures |
| 9. | | Quantum transport, density matrix, Green's and Wigner's functions |
| 10. | | Resonance tunnelling, transport of electrons in superlattices |
| 11. | | Single electron transport, Coulomb's blockade |
| 12. | | Ballistic transport |
| 13. | | Optical phenomena |
| 14. | | Transport in organic materials |
Exercises outline:
| 1. | | Technogical approaches in nanotechnology |
| 2. | | Lithography technique - laser direct writing |
| 3. | | Etching and layer deposition including ALD |
| 4. | | Individual project - device preparation in the laboratory |
| 5. | | Individual project - device preparation in the laboratory |
| 6. | | Individual project - device preparation in the laboratory |
| 7. | | Individual project - device preparation in the laboratory |
8 Project midterm presentation
| 9. | | Characterisation techniques - electrical, optical including Raman |
| 10. | | Individual project - device characterisation in the laboratory |
| 11. | | Individual project - device characterisation in the laboratory |
| 12. | | Individual project - device characterisation in the laboratory |
| 13. | | Individual project - device characterisation in the laboratory |
| 14. | | Project final presentation |
Literature:
| M. | | Lundstrom: Fundamental of Carrier transport, 2nd Ed., Cambridge university press 2000 |
| P. | | Harrison: Quantum Wells, Wires and Dots, Wiley 2000 |
| M. | | L. Cohen, S.G.Louie: Fundamentals of Condensed Matter Physics, Cambidge Univ. Press 2016 |
| K. | | Goser, P. Glösekötter, J. Dienstuhl: Nanoelectronics and Nanosystems, Springer, 2004. |
Ch. Kittel: Introduction to Solid State Physics, 8th ed., Wiley 2005
Requirements:
Solid State Physics
Note:
| Physics of Advanced Semiconductor Devices and Materials |
Keywords:
Nanotechnology, quantum transport, material characterisation
Subject is included into these academic programs:
| Page updated 19.4.2024 14:51:19, semester: Z/2024-5, Z,L/2023-4, Send comments about the content to the Administrators of the Academic Programs |
Proposal and Realization: I. Halaška (K336), J. Novák (K336) |