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- 1. 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)
- 2. Phys. Rev. Lett. 5, 309 (1960) , “Paramagnetic Resonance Absorption from Acceptors in Silicon”, G. Feher, J. C. Hensel, and E. A. GereIn the past,several attempts to observe the paramagnetic absorption from acceptors in silicon were unsuccessful.The reasons for this failure were pointed out by Kohn and are associated with the degeneracy of the valence band in silicon.We wish to report in this Letter the observation of the... (Read more)
- 3. J. Appl. Phys. 35, 379-397 (1964) , “Diffusion and Solubility of Copper in Extrinsic and Intrinsic Germanium, Silicon, and Gallium Arsenide”, R. N. Hall and J. H. RacetteThe solubilities of substitutional and interstitial copper (Cus and Cui) have been measured in intrinsic and extrinsic n- and p-type Ge, Si, and GaAs, using Cu64. These measurements show that Cus is a triple acceptor in... (Read more)
- 4. Phys. Rev. 149, 687 (1966) , “Electron Paramagnetic Resonance and Electrical Properties of the Dominant Paramagnetic Defect in Electron-Irradiated p-Type Silicon”, N. Almeleh, B. Goldstein.Lattice defects having strong paramagnetic resonances are introduced into p-type silicon that has been bombarded with electrons. We have studied the paramagnetic properties and growth of the dominant defect so introduced (the K center) as functions of electron flux and bombardment energy under... (Read more)
- 5. Sov. Phys. JETP 31, 677-679 (1970) , “Electron Paramagnetic Resonance in Plastically Deformed Silicon”, V. A. Grazhulis, Yu. A. Osipyan.Lightly doped silicon crystals were investigated experimentally by the electron paramagnetic resonance method. Paramagnetic centers, generated during plastic deformation of these crystals, were detected. The concentration of these centers increased monotonically with increasing degree of deformation. The EPR spectrum of these centers was anisotropic and had a partially resolved fine structure. The centers werestrongly annealed only at temperature T ≧ 600ºC and the activation energy of the annealing process was ~2 eV. It was concluded that these centers were due to electrons of broken bonds in the cores of dislocations with edge components.
- 6. Jpn. J. Appl. Phys. 10, 52-62 (1971) , “Study of Silicon-Silicon Dioxide Structure by Electron Spin Resonance I”, Y. NishiThree kinds of paramagnetic centers named PA, PB and PC have been found in a silicon-silicon dioxide structure at liquid nitrogen temperature. PA (g=∼2.000, ΔH=∼4 Oe), and PB having anisotropic g-value... (Read more)
- 7. Sov. Phys. Semicond. 5, 1930 (1972) , “EPR of Zinc Atoms in p-Type Silicon”, V. B. Ginodman, P. S. Gladkov, B. G. Zhurkin, B. V. Kornilov.Zinc is a double accepter in silicon and it introduces two levels, E + 0.31 and E + 0.55 eV, into forbidden band [1,2]. The electrical and optical properties of zinc-doped silicon have been investigated by several workers [2-4]. A brief report of the observation of EPR in silicon is given in [5,6]: in these investigations the magnetic field H was perpendicular to the axis of compression of a crystal. Uniaxial compression gave rise to a structure in EPR spectrum of Zn67 and this structure was attributed to the hyperfine interaction of an unpaired hole with the magnetic moment of the Zn67 nucleus. The present paper describes the result of an investigation of the EPR of the Zn- state of zinc in p-type silicon doped with zinc in p-type silicon doped with zinc and phosphorus. The investigation was carried out at liquid helium temperature.
- 8. Phys. Rev. B 7, 4547 (1973) , “Raman Scattering and Photoluminescence in Boron-Doped and Arsenic-Doped Silicon”, J. M. Cherlow, R. L. Aggarwal, and B. LaxThe deformation potentials and g values of the ground state of the boron acceptor in silicon have been determined from a study of the stress and Zeeman splitting of the electronic Raman scattering in this material. The stress splitting of the Raman line results from a twofold splitting of the... (Read more)
- 9. Phys. Rev. B 9, 2607 (1974) , “EPR of a Jahn-Teller distorted (111) carbon interstitialcy in irradiated silicon”, K. L. Brower.An electron-paramagnetic-resonance (EPR) study of irradiated, p-type silicon doped with carbon enriched with 13C has revealed that the Si-G11 spectrum possesses a 13C hyperfine structure. Owing to the complexity and lack of resolution in the observed spectrum, we found it... (Read more)
- 10. Lattice Defects in Semiconductors 23, 1-22 (1975) , Institute of Physics, London , “EPR Studies of the Lattice Vacancy and Low-Temperature Damage Processes in Silocon”, G. D. Watkins.EPR studies of silicon irradiated at 20.4 K and 4.2 K by 1.5 MeV and 46 MeV electrons are described. In 46 MeV irradiations the dominant defects formed appear to be divavancies and other multiple defect aggregates which liberate vacancies throughout the anneal to room temperature as they reorder, recombine, etc. For 1.5 MeV irradiations group III atoms play a vital role in p- and n-type materials in trapping interstitials and stabilizing damage. Carbon and oxygen are not effective interstitial traps at these temperatures. Evidence of limited vacancy migration during irradiation is also cited. Two distinct excited configurations of vacancy-oxygen pairs are identified as precursors to A-centre formation in n-type silicon. The kinetics for their conversion to A-centres depends strongly upon the Fermi level as does the isolated vacancy migration energy whhich is measured to be 0.18 ± 0.02 eV for the V= charge state. The vacancy has four charge states, V+, V0, V- and V=. Kinetics for hole release from V+ reveals an activation barrier of 0.057 eV. The concentration of V+ at 20.4 K in boron-doped material indicates the corresponding donor level even closer to the band edge, approximately EV + 0.039 eV. Jahn-Teller energies for V0, V+, and V- are estimated from stress-alignment studies and confirmed to be large. Kinetics studies for reorientation from one Jahn-Teller distortion to another are also described for each charge state.
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