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- 1. Appl. Phys. Lett. 91, 122109 (2007) , “Determining the defect parameters of the deep aluminum-related defect center in silicon”, Philipp Rosenits, Thomas Roth, Stefan W. Glunz, and Svetlana BeljakowaThrough a combined application of two characterization methods, deep-level transient spectroscopy and lifetime spectroscopy, the lifetime-limiting defect level in intentionally aluminum-contaminated Czochralski silicon has been analyzed and a complete set of defect parameters could be obtained. This... (Read more)
- 2. Physica B 302-303, 249-256 (2001) , “Hydrogen-Enhanced Clusterization of Intrinsic Defects and Impurities in Silicon”, B. N. Mukashev, Kh. A. Abdullin, Yu. V. Gorelkinskii, M. F. Tamendarov and S. Zh. TokmoldinFormation of intrinsic and impurity defect complexes in hydrogenated monocrystalline silicon is studied. Hydrogen was incorporated into samples by different ways: either by proton implantation at 80 and 300 K, or by annealing at 1250°C for 30–60 min in a sealed quartz ampoule containing... (Read more)
- 3. Mater. Sci. Eng. B 58, 171-178 (1999) , “Self-Interstitial Related Reactions in Silicon Irradiated by Light Ions”, B. N. Mukashev, Kh. A. Abdullin, Yu. V. Gorelkinskii and S. Zh. TokmoldinRecent deep level transient spectroscopy (DLTS), electron paramagnetic resonance (EPR) and infrared (IR) spectroscopy data on interactions of self-interstitial with carbon, aluminium, oxygen and hydrogen in silicon irradiated by light ions are reviewed. Self-interstitial behaviour in silicon was... (Read more)
- 4. phys. stat. sol. (a) 168, 73 (1998) , “Self-Interstitials in Silicon Irradiated with Light Ions”, B. N. Mukashev, Kh. A. Abdullin, Yu. V. Gorelkinskii.The behavior of self-interstitials in silicon which was irradiated with light ions (protons and -particles) and electrons was explored by monitoring known impurity interstitial centers (Ci, Ali, (Si-O)i) with deep level transient spectroscopy (DLTS) and electron... (Read more)
- 5. phys. stat. sol. (a) 86, 313 (1984) , “New EPR Defects in Si<Al>”, A. V. Dvurechenskii, B. P. Kashnikov, V. V. Suprunchik.Two new paramagnetic centres, labeled Si-H5 and Si-H6 are found in silicon containing aluminium (6 × 1017 to 5 × 1018 cm-3) and irradiated with high dose of 1 Me V electrons (up to 2 × 1020 cm-2). Spin-Hamiltonian constants of the Si-H5... (Read more)
- 6. Phys. Rev. B 1, 1908 (1970) , “Electron Paramagnetic Resonance of the Aluminum interstitial in Silicon”, Keith L. BrowerElectron-paramagnetic-resonance spectra of the Al++ interstitial (Si-G18) produced in aluminum-doped (p-type) silicon by room temperature or 4°K electron irradiations are presented and show that the Al++ is located in the tetrahedral interstitial site. The hyperfine... (Read more)
- 7. Phys. Rev. 155, 802 (1967) , “Defects in Irradiated Silicon: Electron Paramagnetic Resonance and Electron-Nuclear Double Resonance of the Aluminum-Vacancy Pair”, G. D. Watkins.An EPR spectrum produced in aluminum-doped silicon by 1.5-MeV electron irradiation is described. Labeled Si G9, it is identified as arising from an aluminum-vacancy pair, presumably formed when a mobile lattice vacancy is trapped by substitutional aluminum. The resonance is observed only upon... (Read more)
- 8. Radiation Damage in Semiconductors 97-113 (1965) , Dunod, Paris , “A Review of EPR Studies in Irradiated Silicon”, G. D. Watkins.1. INTRODUCTION (p.97): 2. THE EPR EXPERIMENT (p.97): 3. RESULTS (p.99): A. The lattice Vacancy (p.99), B. Vacancies Trapped by Other Defects (p.102), C. Vacancy Motion (p.103), D. Interstitial Defects (p.103), E. Other Spectra (p.105), 4. SUMMARY AND CONCLUSION (p.110): 5.ACKNOWLEDGMENTS (p.110):
- 9. Solid State Physics 5, 258-319 (1957) , Academic Press, New York (Edited by F. Seitz, D. Turnbull) , “Shallow Impurity States in Silicon and Germanium”, W. KohnI. Introduction (p.258): II. Emprical Properties (p.261): 1. Energy Levels (p.261), a. Ionization Energies, b. Spectra of Excited States, 2. Spin Resonance (p.266), a. Electron Spin Resonance, b. Double Resonance, 3. Static Magnetic Susceptibility (p.271), III. Structure of Donor States (p.271): 4. Conduction Bands of Silicon and Germanium (p.271), a. Silicon, b. Germanium, 5. Effective Mass Theory of Donor States (p.274), a. Single Band Minimum at k=0, b. Several Conduction Band Minima, c. Matrix Elements for Radiative Transitions, 6. Numerical Results and Comparison with Experiments (p.285), a. Energy Levels, b. Wave Functions, 7. Corrections to the Effective Mass Formalism (p.289), a. General Considerations, b. Corrected Wave Functions, c. Comparison with Experiment, IV. Structure of Acceptor States (p.297): 8. Valence Bands of Silicon and Germanium (p.297), a. Silicon, b. Germanium, 9. Effective Mass Equations for Acceptor States (p.300), 10. Approximate Solutions and Comparison with Experiment (p.301) a. Germanium b. Silicon V.Effects of Strains and of Static Electric and Magnetic Fields (p.306): 11. Strains (p.306) a. Donor States, b. Acceptor States, 12. Stark Effect (p.311)
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