Boron Nitride

Neuberger, M.

doi:10.1007/978-1-4615-9606-6_8

M. Neuberger²

223 Accesses

This is a preview of subscription content, log in via an institution to check access.

Access this chapter

Log in via an institution

eBook: USD 16.99; Price excludes VAT (USA)

Softcover Book: USD 16.99; Price excludes VAT (USA)

Tax calculation will be finalised at checkout

Purchases are for personal use only

Institutional subscriptions

Preview

Unable to display preview. Download preview PDF.

Boron Nitride Bibliography

ALESHIN, V.G. et al. Band Structure of Cubic Boron Nitride. SOVIET PHYS.-SOLID STATE, v. 10, no. 9, Mar. 1969. p. 2282–2283.
Google Scholar
AUTIO, G.W. and E. SCALA. The Effect of Anisotropy on Emissivity. CARBON, v. 6, no. 1, Feb. 1968. p. 41–54.
Article Google Scholar
BASCHE, M. and D. SCHIFF. New Pyrolytic Boron Nitride. MATERIALS IN DESIGN ENG., v. 59, no. 2, Feb. 1964. p. 78–81.
Google Scholar
BASSANI, F. and M. YOSHIMINE. Electronic Band Structure of Group IV Elements and III–V Compounds. PHYS. REV., v. 130, no. 1, Apr. 1963. p. 20–33.
Article MATH Google Scholar
BOSE, D.N. and H.K. HENISCH. Thermoluminescence in Boron Nitride Powders. AMERICAN CERAM. SOC., J., v. 52, no. 5, May 1970. p. 281–282.
Google Scholar
BRAFMAN, O. et al. Raman Spectra of Aluminum Nitride, Cubic Boron Nitride and Boron Phosphide. SOLID STATE COMMUNICATIONS, v. 6, no. 8, Aug. 1968. p. 523–526.
Article Google Scholar
BRAME, E.G. et al. Infra-red Spectra of Inorganic Solids. II. Oxides, Nitrides, Carbides and Borides. J. INORG. NUCL. CHEM., v. 5, 1957. p. 48–52.
Article Google Scholar
DONNAY, J.D.H. (Ed.) Crystal Data. Determinative Tables. 2nd Ed. American Crystallographic Association. April 1963. ACA Monograph no, 5.
Google Scholar
DULIN, I.N. Phase Transformations in Boron Nitride Caused by Dynamic Compression. SOVIET PHYS.-SOLID STATE, v. 11, no. 5, Nov. 1969. p. 1016–1020.
Google Scholar
DWORKIN, A.S. et al. The Thermodynamics of Boron Nitride; Low-Temperature Heat Capacity and Entropy; Heats of Combustion and Formation. J. OF CHEM. PHYS., v. 22, no. 5, May 1954. p. 837–842.
Article Google Scholar
FILONENKO, N.E. et al. Crystal Morphology of Cubic Boron Nitride. DOKL. AKAD. NAUK SSSR, v. 164, no. 6, 1965. p. 1286–1288.
Google Scholar
GEICK, R. et al. Normal Modes in Hexagonal Boron Nitride. PHYS. REV., v. 146, no. 2, June 1966. p. 543–547.
Article Google Scholar
GIELISSE, P.J. et al. Lattice Infrared Spectra of Boron Nitride and Boron Monophosphide. PHYS. REV., v. 155, no. 3, Mar. 1967. p. 1039–1046.
Article Google Scholar
GOLDWATER, D.L. and R.E. HADDAD, Certain Refractory Compounds as Thermionic Emitters. J. OF APPLIED PHYS., v. 22, no. 1, Jan. 1951. p. 70–73.
Article Google Scholar
GORYUNOVA, N.A. The Chemistry of Diamond-Like Semiconductors. Ed. J.C. Anderson. Cambridge, Mass. The M.I.T. Press, Mass. Inst. Tech., 1965. 236 p.
Google Scholar
MOTOROLA, INC Acoustic Amplification in III-V Compounds. By: HICKERNELL, F. and M. MEDINA. Interim Report no. 1, Nov. 1, 1963-Feb, 1, 1964, Contract no. AF 33-615-1109, Feb. 1, 1964. AD 465 234.
Google Scholar
HIGH TEMPERATURES MATERIALS, INC., LOWELL, MASS. Boralloy, Boron Nitride. Data Sheet, Feb. 1965. 12 p.
Google Scholar
KLEINMAN, L. and J.C. PHILLIPS. Crystal Potential and Energy Bands of Semiconductors. II. Self-Consistent Calculations for Cubic Boron Nitride. PHYS. REV., v. 117, no. 2, Jan. 1960. p. 460–464.
Article Google Scholar
WESTINGHOUSE ELEC CORP., LIMA, OHIO. AEROSPACE ELEC. DIV. Development and Evaluation of Magnetic and Electrical Materials Capable of Operating in the 800 to 1600°F Range. By: KUESER, P.E. et al. 3rd QR. Rept. no. NASA-CR-54356, Sept. 1965. 175 p. N66 32924.
Google Scholar
RAYTHEON MANUF. CO., RES. DIV. WALTHAM, MASS. Chemically Vapor-Deposited Boron Nitride. By: LI, P.C. et al. Proc. of the OSU-RTD Symp. on Electromagnetic Windows. Contract no. AF 33 615-1080. June 2–4, 1964. N65-11827.
Google Scholar
McCARTHY, D.E. The Reflection and Transmission of Infrared Materials. V. Spectra from 2 to 50 Microns. APPLIED OPTICS, v. 7, no. 10, Oct. 1968, p. 1997–2000.
Article Google Scholar
NOREIKA, A.J. and M.H. FRANCOMBE. Structural, Optical and Dielectric Properties of Reactively Sputtered Films in the System Aluminum Nitride-Boron Nitride. J. VACUUM SCIENCE TECH., v. 6, no. 4, July/Aug. 1969, p, 722–726.
Article Google Scholar
PEASE, R.S. An x-Ray Study of Boron Nitride. ACTA CRYSTALLOGRAPHICA, v. 5, 1952. p. 356–361.
Article Google Scholar
PHILIPP, H.R. and E.A. TAFT. Optical Properties of Diamond in the Vacuum Ultraviolet. PHYS. REV., v. 127, no. 1, July 1962. p. 159–161.
Article Google Scholar
POWELL, R.W. and R.P. TYE. Thermal Conductivity of Ceramic Materials and Measurements with a New Form of Thermal Comparator. BRITISH CERAM. SOC., PROC., Special Ceramics, 1962. N.Y. Acad. Press, 1963. p. 261–277.
Google Scholar
RAND, M.J. and J.F. ROBERTS. Preparation and Properties of Thin Film Boron Nitride. ELECTROCHEM. SOC., J., v. 115, no. 4. Apr. 1968. p. 423–429.
Article Google Scholar
ROEMELT, G. Paramagnetic Electron Resonance in Boron Nitride Centres which Have Been Generated Either Thermally or by Irradiation (In Ger.). Z. FUER NATURFORSCHUNG, v. 21a, no. 11, Nov. 1966. p. 1970–1975.
Google Scholar
SAMSONOV, G.V. et al. Boron, Its Compounds and Alloys. U.S. Atomic Energy Commission, Div. of Tech. Info. AEC tr. 5032, v. 1, 1960. p. 211. [A]
Google Scholar
SAMSONOV, G.V. et al. Emission Coefficient of High-Melting Compounds. SOVIET POWDER METALL. AND METAL. CERAM., no. 5, May 1969, p. 374–379. [B]
Google Scholar
LEXINGTON LABS., INC. CAMBRIDGE, MASS. High Temperature Electrical Conductivity Device for Use with Thermal Image Heating. By: SCHAFFER, P.S. et al. Final Rept,, Dec 15, 1964. Contract no, AF 19 628-1616. 62 p. AD 610-496.
Google Scholar
SCLAR, C.B. and C.M. SCHWARTZ. Relation of Molar Refraction to Coordination in Polymorphs of Boron Nitride and Carbon. Z. FUER KRISTALLOGRAPHIE, v. 121, 1965. p. 463–466.
Google Scholar
SOUTHERN RESEARCH INSTITUTE. The Thermal Properties of 26 Solid Materials to 5000°F or Their Destruction Temperatures. ASD-TDR-62-765. Contract no. AF 33 616-7319. Jan. 1963. AD 298 061.
Google Scholar
WESTINGHOUSE ELECTRIC CORP. Magnetic and Electrical Materials Capable of Operating in the 800 to 1600°F Temperature Range. By: STAPLETON, R.E. Dec. 1968. 129 p. N69-14400.
Google Scholar
STEIGMEIER, E.F. The Debye Temperature of III–V Compounds. APPLIED PHYS. LETTERS, v. 3, no. 1, July 1963. p, 6–8.
Article Google Scholar
TAYLOR, K.M. Hot Pressed Boron Nitride. INDUSTRIAL AND ENG. CHEM., v. 47, no. 12, Dec. 1955. p. 2506–2509.
Article Google Scholar
WENTORF, R.H., Jr. Cubic Form of Boron Nitride. J. OF CHEM. PHYS., v. 25, no. 4, Apr. 1957. p. 956.
Article Google Scholar
WIFF, D.R. and R. KEOWN. Energy Bands in Cubic Boron Nitride. J. OF CHEM. PHYS., v. 47, no. 9, Nov. 1967. p. 3113–3119.
Article Google Scholar

Download references

Author information

Authors and Affiliations

Electronic Properties Information Center, Hughes Aircraft Company, Culver City, California, USA
M. Neuberger

Authors

M. Neuberger
View author publications
You can also search for this author in PubMed Google Scholar

Rights and permissions

Reprints and permissions

Copyright information

About this chapter

Cite this chapter

Neuberger, M. (1971). Boron Nitride. In: III–V Semiconducting Compounds. Springer, Boston, MA. https://doi.org/10.1007/978-1-4615-9606-6_8

Download citation

DOI: https://doi.org/10.1007/978-1-4615-9606-6_8
Publisher Name: Springer, Boston, MA
Print ISBN: 978-1-4615-9608-0
Online ISBN: 978-1-4615-9606-6
eBook Packages: Springer Book Archive

Publish with us

Policies and ethics