Electron Spin Resonance Recombination Radiation Natural Diamond Soviet Phys Intrinsic Edge Absorption 
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Diamond Bibliography

  1. ANGRESS, J.F. et al. One-Phonon Band-Mode Absorption by Impurity Resonances in Diamond and Silicon. ROYAL SOC. OF LONDON, PROC., v. 308, no. 1492, Dec. 1968. p. 111–124.CrossRefGoogle Scholar
  2. ARLT, G. and G.R. SCHODDER. Some Elastic Constants of Sic. ACOUSTICAL SOC. OF AMERICA, J., v. 37, no. 2, Feb. 1965. p. 384–386.CrossRefGoogle Scholar
  3. BELL, M.D. and W.J. LEIVO. Electron Spin Resonance in Semiconducting Diamonds. J. OF APPLIED PHYS., v. 38, no. 1, Jan. 1967. p. 337–339.CrossRefGoogle Scholar
  4. BERMAN, R. et al. The Thermal Conductivity of Diamond at Low Temperatures. ROYAL SOC. OF LONDON, PROC, SER. A. v. 220, no. 1140, Oct. 22, 1953. p. 171–183. [A]CrossRefGoogle Scholar
  5. BERMAN, R. et al. The Thermal Conductivity of Dielectric Crystals: The Effect of Isotopes. ROYAL SOC. OF LONDON, PROC, SER. A, v. 237, no. 1210, Nov. 1956. p. 344–354. [B]CrossRefGoogle Scholar
  6. BEZRUKOV, G.N. et al. Some Electrical and Optical Properties of Synthetic Semiconducting Diamonds Doped with Boron. SOVIET PHYS. SEMICONDUCTORS, v. 4, no. 4, Oct. 1970. p. 587–590.Google Scholar
  7. BOCHKO, V.A. and Yu.L. ORLOV. Variation of Density in Varieties of Natural Diamonds. SOVIET PHYS.-DOKLADY, v. 15, no. 3, Sept. 1970. p. 204–207.Google Scholar
  8. BUNDY, F.P. Direct Conversion of Graphite to Diamond in Static Pressure Apparatus. J. OF CHEM. PHYS., v. 38, no. 3, Feb. 1963. p. 631–643.CrossRefGoogle Scholar
  9. BUNDY, F.P. and J.S. KASPER. Hexagonal Diamond-A New Form of Carbon. J. OF CHEM. PHYS., v. 46, no. 9, May 1, 1967. p. 3437–3446.CrossRefGoogle Scholar
  10. BURK, D.L. and S.A. FRIEDBERG. Atomic Heat of a Diamond from 11 Degrees to 200 Degrees K. PHYS. REV., v. 111, no. 5, Sept. 1, 1958. p. 1275–1282.CrossRefGoogle Scholar
  11. BURSTEIN, E. and P.L. SMITH. The Photoelastic Properties of Diamond. PHYS. REV., v. 74, Dec. 1948. p. 1880–1881.CrossRefGoogle Scholar
  12. CLARK, C.D. et al. Intrinsic Edge Absorption in Diamond. ROYAL SOC OF LONDON, PROC, A, v. 277, no. 1370, Feb. 11, 1964. p. 312–329. [B]CrossRefGoogle Scholar
  13. CLARK, C.D. et al. The Absorption Spectra of Natural and Irradiated Diamonds. ROYAL SOC OF LONDON, PROC, SER. A, v. 234, no. 1198, Feb. 21, 1956. p. 363–381. [A]CrossRefGoogle Scholar
  14. COLLINS, A.T. and E.C LIGHTOWLERS. Photothermal Ionization and Phono-Induced Tunneling in the Acceptor Photoconductivity Spectrum of Semiconducting Diamond. PHYS. REV., v. 171, no. 3, July 15, 1968. p. 843–855.CrossRefGoogle Scholar
  15. CROWTHER, P.A. et al. Excitation Spectrum of aluminum Acceptors in Diamond under Uniaxial Stress. PHYS. REV., v. 154, no. 3, Feb. 15, 1967. p. 772–785.CrossRefGoogle Scholar
  16. CROWTHER, P.A. and P.J. DEAN. Phonon Inter-actions, Piezo-Optical Properties and the Inter-Relationship of the Nitrogen 3 and Nitrogen 9 Absorption-Emission Systems in Diamond. J. OF PHYS. and CHEM. OF SOLIDS, v. 28, no. 7, July 1967. p. 1115–1116.CrossRefGoogle Scholar
  17. DANA, J.D. System of Mineralogy, 7th Ed. Palache, C et al. v. 1, N.Y., John Wiley & Sons, Inc., 1944, 834 p.Google Scholar
  18. DEAN, P.J. et al. Intrinsic and Extrinsic Recombination Radiation from Natural and Synthetic Aluminum-Doped Diamond. PHYS. REV., v. 140, no. 1A, Oct. 4, 1965. p. A352–A368.CrossRefGoogle Scholar
  19. DEAN, P.J. and P.A. CROWTHER. The Effect of Uniaxial and Hydrostatic Pressure on the Absorption Edge Spectrum and the Edge Excitation Spectrum for Visible Luminescence Diamond. In Int. Conf. on Semiconductor Phys., Proc, 7th, Paris, 1964. v. 4, Ed. by: HULIN, M. N.Y., Acad. Press, 1964. p. 103–112.Google Scholar
  20. DEAN, P.J. and I.H. JONES. Recombination Radiation from Diamond. PHYS. REV., v. 13.3, no. 6A, Mar. 16, 1964. p. A1698–A1705.CrossRefGoogle Scholar
  21. DENHAM, P. et al. Ultraviolet Intrinsic and Extrinsic Photoconductivity of Natural Diamond. PHYS. REV., v. 161, no. 3, Sept. 15, 1967. p. 762–768.CrossRefGoogle Scholar
  22. DESNOYERS, J.E. and J.A. MORRISON. The Heat Capacity of Diamond between 12.8 and 227 K. PHIL. MAC, v. 3, no. 25, Jan. 1958. p. 42–49.CrossRefGoogle Scholar
  23. DESORBO, W. Specific Heat of Diamond at Low Temperatures. J. OF CHEM. PHYS., v. 21, no. 5, May 1953. p. 876–880.CrossRefGoogle Scholar
  24. DONNAY, J.D.H. (Ed.) Crystal Data. Determinative Tables. 2nd Ed. American Crystallography Assoc., 1963.Google Scholar
  25. EVANS, T. and C. PHAAL. Imperfections in Type I and Type II Diamonds. ROYAL SOC OF LONDON, PROC., A, v. 270, no. 1343, Dec. 11, 1962. p. 538–551.CrossRefGoogle Scholar
  26. GIBBS, D.F. and G.J. HILL. The Variation of the Dielectric Constant of Diamond with Pressure. PHIL. MAC. v. 9, no. 99, Mar. 1964. p. 367–375.CrossRefGoogle Scholar
  27. GMELINS HANDBUCH DER ANORGANISCHEN CHEMIE; achte völlig neu bearbeitete Auflage. Carbon. Teil B. Weinheim, Verlag Chemie, GmbH, 1967Google Scholar
  28. PENNSYLVANIA STATE UNIV., UNIVERSITY P.K., P.A. COLL. of Earth and Mineral Sci. NATURAL and SYNTHETIC DIAMONDS and THE NORTH AMERICAN OUTLOOK, by Gold, P.P., v. 37, no. 5, Feb. 1968. p. 37–48.Google Scholar
  29. GOLDSMID, H.J., et al. The Thermoelectric Power of a Semiconducting Diamond. PHYS. SOC., PROC., v. 73, Mar. 1959. p. 393–398.CrossRefGoogle Scholar
  30. GORYUNOVA, N.A. The Chemistry of Diamond-like Semiconductors. Ed. J.D. Anderson, The M.I.T. Press, Mass. Inst, of Tech., Cambridge, Mass. 1963, 236 p.Google Scholar
  31. HARDY, J.R. and S.D. SMITH. Two-phonon Infra-red Lattice Absorption in Diamond. PHILOSOPHICAL MAG., v. 6, no. 69, Sept. 1961. p. 1163–1172.CrossRefGoogle Scholar
  32. JOHNSON, C., et al. Photoeffects and Related Properties of Semiconducting Diamonds. J. OF PHYS. and CHEM. OF SOLIDS, v. 25, no. 8, Aug. 1964. p. 827–836.CrossRefGoogle Scholar
  33. KLINGSPORN, P.E. et al. Analysis of an Electron Spin Resonance Spectrum in Natural diamonds. J. OF APPLIED PHYS., v. 41, no. 7, June 1970. p. 2977–2980.CrossRefGoogle Scholar
  34. KONOROVA, E.A., et al. Ionization Currents in Diamonds During Irradiation with 500–1000 keV Electrons. SOVIET PHYS.-SOLID STATE, v. 8, no. 1, July 1966. p. 1–5.Google Scholar
  35. KONOROVA, E.A. and S.A. SHEVCHENKO. Investigation of the Carrier Mobility in Diamonds. SOVIET PHYS.-SEMICONDUCTORS, v. 1, no. 3, Sept. 1967. p. 299–304.Google Scholar
  36. LARSON, E.S. and H. BERMAN. The Microscopic Determination of the Nonopaque Minerals. U.S. Dept. of the Interior Geological Survey, Bull. 848, 2nd Ed. U.S. Govt. Printing Office, Washington, D.C. 1934.Google Scholar
  37. LIGHTOWLERS, E.C. and A.T. COLLINS. Electrical-Transport Measurements on Synthetic Semiconducting Diamond. PHYS. REV., v. 151, no. 2, Nov. 11, 1966. p. 685–688.CrossRefGoogle Scholar
  38. OKLAHOMA STATE UNIV. OF AGRICULTURE and APPLIED SCI., RES. FOUNDATION. Stillwater. Photoelectric Emission and Surface States of Semiconducting Diamonds. AFCRL-65–489 FR, by LEIVO, W.J, et al. Contract no. AF 19 628–2385. May 28, 1965. 108 p. AD 619 724.Google Scholar
  39. MCSKIMIN, H.J. and W.L. BOND. Elastic Moduli of Diamond. PHYS. REV., v. 105, no. 1, Jan. 1957. p. 116–121.CrossRefGoogle Scholar
  40. MYKOLAJEWYCZ, R., et al. Some Physical Properties of Nearly Perfect Natural Diamond. APPLIED PHYS. LETTERS, v. 6, no. 11, June 1, 1965. p. 227–228.CrossRefGoogle Scholar
  41. NARASIMHAN, P.T. Temperature Dependence of Dielectric Constant of Diamond. PROC. PHYS. SOC. LONDON, v. B68, part 5, May 1955.Google Scholar
  42. PECKHAM, G. The Phonon Disperson Relation for Diamond. SOLID STATE COMMUNICATIONS, v. 5, no. 4, Apr. 1967. p. 311–313.CrossRefGoogle Scholar
  43. PHILIPP, H.R. and E.A. TAFT. Optical Properties of Diamond in the Vacuum Ultraviolet. PHYS. REV., v. 127, no. 1, p. 159–161, July 1, 1962.CrossRefGoogle Scholar
  44. RAUCH, C.J. Millimeter Cyclotron Resonance Experiments in Diamond. PHYS. REV. LETTERS, v. 7, no. 3, Aug. 1, 1961. p. 83–84. [A]CrossRefGoogle Scholar
  45. RAUCH, C.J. Millimeter Cyclotron Resonance in Diamond. In, Internat. Conf. on the Phys. of Semiconductors, proc. Held at Exeter, July 1962. Ed. by: STICKLAND, A.C. London, Inst, of Phys. and the Phys. Soc, 1962. p. 276–280. [B]Google Scholar
  46. REDFIELD, A.G. Electronic Hall Effect in Diamond. PHYS. REV., v. 94, no. 3, May 1, 1954. p. 526–537.CrossRefGoogle Scholar
  47. ROBERTS, R.A. and W.C. WALKER. Optical Study of the Electronic Structure of Diamond. PHYS. REV., v. 161, no. 3, Sept. 1967. p. 730–735.CrossRefGoogle Scholar
  48. SIGAMONY, A. Magnetic Susceptibility of Diamond. INDIAN ACAD. OF SCIENCES, PROC, A, V. 19, May 1944. p. 310–314.Google Scholar
  49. SIROTA, N.N. and A.U. SHELEG. Magnetic Suceptibility of Semiconducting Elements of Group IV Determined on the Basis of X-Ray Analysis. SOVIET PHYS.-DOKL., v. 8, no. 9, Mar. 1964. p. 887–889.Google Scholar
  50. SOBOLEV, E.V. et al. Aluminum Impurities in Diamond Absorption Spectra. SOVIET PHYS., SOLID STATE, v. 11, no. 1, July 1969. p. 200–202.Google Scholar
  51. SOKHOR, M.I. and V.D. VITOL. X-Ray Investigation of Thermal Expansion in Synthetic and Natural Diamonds. SOVIET PHYS. CRYSTALLOGRAPHY, v. 11, no. 4, Jan/Feb. 1970. p. 632–633.Google Scholar
  52. SOLIN, S.A. and A.K. RAMDAS. Raman Spectrum of Diamond. PHYS. REV. B, Ser. 3, v. 1, no. 4, Feb. 15, 1970. p. 1687–1698.CrossRefGoogle Scholar
  53. THEWLIS, J. and A.R. DAVEY. Thermal Expansion of Diamond. PHIL. MAG. v.l, no. 5, May 1956. p. 409–414.Google Scholar
  54. VAVILOV, V.S. et al. Recombination Radiation from Diamonds Caused by Electron Excitation. SOVIET PHYS. SOLID STATE, v. 8, no. 5, Nov. 1966. p. 1210–1214. [A]Google Scholar
  55. VAVILOV, V.S. et al. Investigation of the Hall Effect in p-Type Semiconducting Diamond Doped with Boron by the Ion Implantation Method. SOVIET PHYS. SEMICONDUCTORS, v. 4, no. 1, July 1970. p. 12–16. [B]Google Scholar
  56. VAVILOV, V.S. et al. Investigation During Isochronous Multistage Annealing of the Electrical Conductivity of Semiconducting n- and p-Type Diamonds Prepared by the Ion Implantation Method. SOVIET PHYS. SEMICONDUCTORS, v. 4, no. 1, July 1970. p. 6–11. [C]Google Scholar
  57. VINSOME, P.K.W. and M. JAROS. The Microscopic Dielectric Function in Silicon and Diamond. J. OF PHYS. C., v. 3, no. 10, Oct. 1970. p. 2140–2145.CrossRefGoogle Scholar
  58. WALKER, W.C. and J. OSANTOWSKI. Ultraviolet Optical Properties of Diamond. PHYS. REV., v. 134, no. 1A, Apr. 6, 1964. p. A153–A157.CrossRefGoogle Scholar
  59. WAXLER, R.M. and C.E. WEIR. Effect of Hydrostatic Pressure on the Refractive Indices of Some Solids. NAT. BUREAU OF STANDARDS, J. OF RES., v. 69A, no. 4, July-Aug. 1965. p. 325–333.Google Scholar
  60. WEDEPOHL, P.T. Electrical and Optical Properties of Type IIb Diamonds. PHYS. SOC, PROC, B, v. 70, pt. 2, Feb. 1957. p. 177–185.CrossRefGoogle Scholar
  61. WIGHT, D.R. and P.J. DEAN. Extrinsic Recombination Radiation from Natural Diamond, Exciton Luminescence Associated with the N9 Center. PHYS. REV., v. 154, no. 3, Feb. 15, 1967. p. 689–696.CrossRefGoogle Scholar
  62. WYCKOFF, R.W.G. Crystal Structures. N.Y. Wiley & Sons, v. 1. p. 114.Google Scholar

Copyright information

© IFI/Plenum Data Corporation 1971

Authors and Affiliations

  1. 1.Electronic Properties Information CenterHughes Aircraft CompanyCulver CityUSA

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