Hostname: page-component-77c89778f8-m8s7h Total loading time: 0 Render date: 2024-07-16T15:15:18.092Z Has data issue: false hasContentIssue false
  • English
  • Français

Autobiography

Published online by Cambridge University Press:  26 February 2011

David Turnbull
Get access

Extract

I was born and reared on a family farm in northwest Illinois and obtained my elementary education in a single-teacher village school. Apparently I had a mild case of dyslexia, for I was virtually unable to read until I had been in school for more than two years. Then, through the valiant tutelage of my mother, who had been a school teacher, I suddenly became able to read and ever afterward did so, well and extensively. Our farming community was not included in any secondary school district, and my parents managed to have me admitted to Kewanee High School which, at the time, was considered to be the most outstanding school, academically, in the area. There, indeed, I received an excellent education from an outstanding group of teachers. I was especially inspired by the Misses Minnie Trask and Wildred Ewan, who posed demanding intellectual challenges and encouraged imaginative but rigorous modes of thought. It seemed that I learned most from having to solve difficult problems and rather little from classroom exposition, however excellent it was. Because of this, the emphasis of my own teaching has been on the posing of meaningful and challenging problems. In this, I have tried to follow the dictum, attributed to Galileo, “you can't teach a person anything, you can only help them to find it within themself”.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 57: Symposium I – Phase Transitions in Condensed Systems--Experiments and Theory , 1985 , 1
Copyright
Copyright © Materials Research Society 1987

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Turnbull, D., “Transient Nucleation,” Metals Technology, Technical Publicaton 2365, June 1948.Google Scholar
Fisher, J. C., Hollomon, J. H. and Turnbull, D., “Nucleation”, Journal of Applied Physics 19 (8): 775784, August 1948.Google Scholar
Fisher, J. C., Hollomon, J. H. and Turnbull, D., “Nucleation of Phase Transformations,” Metals Technology, Technical Note 5, 1948.Google Scholar
Turnbull, D. and Fisher, J. C., “Rate of Nucleation in Condensed Systems,” Journal of Chemical Physics, 17 (1): 7173, January 1949.Google Scholar
Fisher, J. C., Hollomon, J. H. and Turnbull, D., “Rate of Nucleation of Solid Particles in a Subcooled Liquid,” Science, 109 (2825): 168, February 1949.Google Scholar
Turnbull, D., “The Subcooling of Liquid Metals,” Journal of Applied Physics, 20 (8): 817, August 1949.Google Scholar
Turnbull, D., “Principles of Solidification,” Thermodynamics in Physical Metallurgy Cleveland: American Society for Metals, pp. 282306, February 1950.Google Scholar
Turnbull, D., “Kinetics of Heterogeneous Nucleation,” Journal of Chemical Physics, 18 (2): 198203, 1950.Google Scholar
Turnbull, D., “Correlation of Liquid-Solid Interfacial Energies Calculated from Supercooling of Small Droplets,” Journal of Chemical Physics, 18 (5): 769, May 1950.CrossRefGoogle Scholar
Turnbull, D., “Isothermal Rate of Solidification of Small Droplets of Mercury and Tin,” Journal of Chemical Physics, 18 (5): 768, May 1950.Google Scholar
Turnbull, D., “The Supercooling of Aggregates of Small Metal Particles,” Journal of Metals, 188: 11441148, September 1950.Google Scholar
Turnbull, D. and Cech, R. E., “Microscopic Observation of the Solidification of Small Metal Droplets,” Journal of Applied Physics, 21 (8): 804810, August 1950.Google Scholar
Turnbull, D., “Formation of Crystal Nuclei in Liquid Metals,” Journal of Applied Physics, 21 (10): 10221028, October 1950.Google Scholar
Cech, R. E. and Turnbull, D., “Microscopic Observation of the Solidification of Cu-Ni Alloy Droplets,” Journal of Metals, Transactions Section, pp. 242243, March 1951.Google Scholar
Hollomon, J. H. and Turnbull, D., “The Nucleation of the Solid,” Transactions of the Metallurgical Society of the AIME, pp. 123 (1951).Google Scholar
Hollomon, J. H. and Turnbull, D., “Solidification of Lead-Tin Alloy Droplets,” Journal of Metals, III (9): 803805, and Transactions AIME, 191: 803–805, 1951.Google Scholar
Turnbull, D., “Kinetics of Solidification of Supercooled Liquid Mercury Droplets,” Journal of Chemical Physics, 20 (3): 411424, March 1952.Google Scholar
Turnbull, D. and Vonnegut, B., “Nucleation Catalysis,” Industrial and Engineering Chemistry, 44 (6): 12921298, 1952.Google Scholar
Turnbull, D., “Theory of Catalysis of Nucleation by Surface Patches,” Journal of Chemical Physics, 20 (8): 1327, August 1952.Google Scholar
Hollomon, J. H. and Turnbull, D., “Nucleation,” in Progress in Metal Physics, 4: 333388, 1953.Google Scholar
Turnbull, D., “Theory of Catalysis of Nucleation by Surface Patches,” Acta Metallurgica, 1: 814, January 1953.CrossRefGoogle Scholar
Fisher, J. C. and Turnbull, D., “Influence of Stress on Martensite Nucleation,” Acta Metallurgica, 1: 310314, May 1953.CrossRefGoogle Scholar
Fisher, J. C. and Turnbull, D., “Calculation of Martensite Nucleus Energy Using the Reaction-Path Model,” Journal of Metals, 5: 12, July 1953.Google Scholar
Turnbull, D., “Role of Structural Impurities in Phase Transformations,” Impurities and Imperfections, American Society of Metals, pp. 121144, 1955.Google Scholar
Turnbull, D., “Remarks on the Theory of Heterogeneous Nucleation of Crystals,” Proceedings Woods Hole Conference, pp. 355360, 1955.Google Scholar
Cech, R. E. and Turnbull, D., “Heterogeneous Nucleation of the Martensite Transformation,” Journal of Metals, pp. 19, February 1956.Google Scholar
Turnbull, D., “Phase Changes,” Solid State Physics, III: 225306, 1956.Google Scholar
Turnbull, D. and Cormia, R. L., “Kinetics of Crystal Nucleation in Some Normal Alkane Liquids,” Journal of Chemical Physics, 34 (3): 820831, March 1961.Google Scholar
Turnbull, D., “The Liquid State and the Liquid-Solid Transition,” The 1961 Institute of Metals Division Lecture, Transactions of the Metallurgical Society of AIME, 221: 422439, June 1961.Google Scholar
Turnbull, D., “On the Relation Between Crystallization Rate and Liquid Structure,” Journal of Physical Chemistry, 66: 609613, April 1962.Google Scholar
Cormia, R. L., Price, F. P. and Turnbull, D., “Kinetics of Crystal Nucleation in Polyethylene,” Journal of Chemical Physics, 37 (6): 13331340, September 1962.CrossRefGoogle Scholar
Turnbull, D., Definitions of “Nucleation,” “Nucleation and Growth in Recrystallization,” “Nucleation Phenomena in Liquids,” “Precipitation in Alloys” and “Transformation, Diffusionless,” Encyclopaedic Dictionary of Physics,” Oxford: Pergamon Press, 1962.Google Scholar
Turnbull, D., “The Undercooling of Liquids,” Scient ific American, 212 (1): 3846, January 1965.CrossRefGoogle Scholar
Burns, J. R. and Turnbull, D., “Kinetics of Crystal Nucleation in Molten Isotactic Polypropylene,” Journal of Applied Physics, 37 (11): 40214026, October 1966.Google Scholar
Burns, J. R. and Turnbull, D., “Nucleation of Crystallization in Molten Isotactic Polybutene-l,” Journal of Polymer Science, 6: 775782, Part A-2, 1968.Google Scholar
Tu, K. N. and Turnbull, D., “Nucleation in Solids: (A) Brief Survey; (B) Cellular Precipitation,” Mechanism of Phase Transformations in Crystalline Solids, pp. 3236, Institute of Metals Monograph, 33, London, 1969.Google Scholar
Spaepen, F. and Turnbull, D., “Formation of Metallic Glasses,” Rapidly Quenched Metals, ed. Grant, N. J. and Giessen, B. C., Second International Conference, pp. 205229, Cambridge, MA: M.I.T. press, 1976.Google Scholar
Turnbull, D. and Spaepen, F., “Crystal Nucleation and the Crystal-Melt Interfacial Tension in Linear Hydrocarbons,” Journal of Polymer Science: Polymer Symposium, 63: 237243, 1978.Google Scholar
Spaepen, F. and Turnbull, D., “Negative Pressures and Melting Point Depression in Oxide-Coated Liquid Metal Droplets,” Scripta Metallurgica, 13: 149151, 1979.Google Scholar
Drehman, A. J. and Turnbull, D., “Solidification Behavior of Undercooled Pd83Si17 and Pd82Si18 Liquid Droplets,” Scripta Metallurgica, 15 (5): 543548, 1981.Google Scholar
Turnbull, D., “Metastable Structures in Metallurgy,” The 1980 Campbell Memorial Lecture, The American Society for Metals, Metallurgical Transactions A 12A: 695708, May 1981.Google Scholar
Turnbull, D., “On Anomalous Prefactors from Analysis of Nucleation Rates,” Progress in Materials Science, Chalmers Anniversary Volume ed. Christian, J. W., Haasen, P. and Massalski, T. B., pp. 269275, London: Pergamon Press, 1981.Google Scholar
Drehman, A. J. and Turnbull, D., “Crystal Nucleation in Pd-Si Alloys,” Materials Processing in the Reduced Gravity Environment of Space, ed. Rindone, G. E., pp. 8185, Amsterdam: North Holland, 1982.Google Scholar
Turnbull, D., “Metastable Solid Phases,” McGraw-Hill Yearbook of Science and Technology, pp. 310312, New York: McGraw-Hill Book Company, 1982/1983.Google Scholar
Turnbull, D., “Kinetics and Metastable Structure Formation in Rapid Solidification Processing,” Proceedings of Second Israel Materials Engineering Conference, Ben Gurion University, Beersheva, ed. Grill, A. and Rokhlin, S. I., pp. 110 (1984).Google Scholar
Turnbull, D., “The Subcooling of Liquid Metals,” Journal of Applied Physics, 20 (8): 817, August 1949.Google Scholar
Turnbull, D. and Cohen, M. H., “Concerning Reconstructive Transformation and Formation of Glass,” Journal of Chemical Physics, 29 (5): 10491054, November 1958.Google Scholar
Cohen, M. H. and Turnbull, D., “Molecular Transport in Liquids and Glasses,” Journal of Chemical Physics, 31 (5): 11641169, November 1959.Google Scholar
Turnbull, D. and Cohen, M. H., “Crystallization Kinetics and Glass Formation,” Modern Aspects of the Vitreous State, ed. MacKenzie, J. D., pp. 3862, London: Butterworth and Co. Publishers Ltd., 1960.Google Scholar
Turnbull, D. and Cormia, R. L., “A Dynamic Hard Sphere Model,” Journal of Applied Physics, 31 (4): 674678, April 1960.Google Scholar
Cohen, M. H. and Turnbull, D., “Composition Requirements for Glass Formation in Metallic and Ionic Systems,” Nature, 189 (4759): 131132, January 1961.Google Scholar
Turnbull, D. and Cohen, M. H., “Free-Volume Model of the Amorphous Phase: Glass Transition,” Journal of Chemical Physics, 34, (1): 120125, January 1961.Google Scholar
Turnbull, D., “The Liquid State and the Liquid-Solid Transition,” The 1961 Institute of Metals Division Lecture, Transactions of the Metallurgical Society of AIME, 221: 422439, June 1961.Google Scholar
Turnbull, D., “On the Relation Between Crystallization Rate and Liquid Structure,” Journal of Physical Chemistry, 66: 609613, April 1962.Google Scholar
Turnbull, D., Definitions of “Nucleation,” “Nucleation and Growth in Recrystallization,” “Nucleation Phenomena in Liquids,” “Precipitation in Alloys” and “Transformation, Diffusionless,” Encyclopaedic Dictionary of Physics,” Oxford: Pergamon Press, 1962.Google Scholar
Cormia, R. L., MacKenzie, J. D. and Turnbull, D., “Viscous Flow and Melt Allotropy of Phosphorus Pentoxide,” Journal of Applied Physics, 34 (8): 2245–2248, August 1963.Google Scholar
Cohen, M. H. and Turnbull, D., “Metastability of Amorphous Structures,” Nature, 203 (4948): 964965, August 1964.Google Scholar
Turnbull, D., “Thermodynamics and Kinetics of Formation of the Glass State and Initial Devitrification,” Physics of Non-Crystalline Solids, Proceedings of the International Conference, Delft, 1964, ed. Prins, J. W., Amsterdam: North Holland Publishing, pp. 4156.Google Scholar
Turnbull, D., “Free Volume Model of the Liquid State,” Liquids: Structure, Properties, Solid Interactions, ed. Hughel, T. J., pp. 624 Amsterdam: Elsevier Publishing Company (1965).Google Scholar
Turnbull, D., “The Undercooling of Liquids,” Scientific American, 212 (1): 3846, January 1965.Google Scholar
Seward, T. P. III, Uhlmann, D. R., Turnbull, D. and Pierce, G. R., “Transmission Electron Microscopy of Thin Glass Samples,” Journal of the American Ceramic Society, 50 (1): 2529, January 1967.Google Scholar
Greet, R. J. and Turnbull, D., “Glass Transition in o-Terphenyl,” Journal of Chemical Physics, 46 (4): 12431251, February 1967.Google Scholar
Chen, H. S. and Turnbull, D., “Thermal Evidence of a Glass Transition in Gold-Silicon-Germanium Alloy,” Applied Physics Letters, 10 (10): 284286, May 1967.Google Scholar
Chen, H. S. and Turnbull, D., “Thermal Properties of Gold-Silicon Binary Alloy Near the Eutectic Composition,” Journal of Applied Physics, 38 (9): 36463650, August 1967.Google Scholar
Greet, R. J. and Turnbull, D., “Test of Adam-Gibbs Liquid Viscosity Model with o-Terphenyl Specific-Heat Data,” Journal of Chemical Physics, 47 (6): 21852190, September 1967.Google Scholar
Bagley, B. G., Chen, H. S. and Turnbull, D., “Characterization of Amorphous Alloy Films,” Material Research Bulletin, 3: 159168, 1968.Google Scholar
Chen, H. S. and Turnbull, D., “The Specific Heat of Tin and Gallium in Their Stable and Undercooled Pure Liquid States,” Acta Metallurgica, 16: 369373, March 1968.Google Scholar
Seward, T. P. III, Uhlmann, D. R. and Turnbull, D., “Phase Separation in the System BaO-SiO2 ,” Journal of the American Ceramic Society, 51 (5): 278285, May 1968.Google Scholar
Chen, H. S. and Turnbull, D., “Evidence of a Glass-Liquid Transition in a Gold-Germanium-Silicon Alloy,” Journal of Chemical Physics, 48 (6): 25602571, March 1968.CrossRefGoogle Scholar
Bagley, B. G. and Turnbull, D., “Structure Study of an Amorphous Electrodeposited Nickel-Phosphorus Alloy,” Journal of Applied Physics, 39 (12): 56815685, November 1968.Google Scholar
Seward, T. P., Uhlmann, D. R. and Turnbull, D., “Development of Two-Phase Structure in Glasses, with Special Reference to the System BaO-SiO2 ,” Journal of the American Ceramic Society, 51 (11): 634643, November 1968.Google Scholar
Chen, H. S. and Turnbull, D., “Formation, Stability and Structure of Palladium-Silicon Based Alloy Glasses,” Acta Metallurgica, 17: 10211031, August 1969.Google Scholar
Turnbull, D., “Under What Conditions Can a Glass be Formed?,” Contemporary Physics, 10 (5): 473488, 1969.CrossRefGoogle Scholar
Chen, H. S. and Turnbull, D., “Specific Heat and Heat of Crystallization of Amorphous Germanium,” Journal of Applied Physics, 40 (10): 42144215, September 1969.CrossRefGoogle Scholar
Chen, H. S. and Turnbull, D., “Formation and Stability of Amorphous Alloys of Au-Ge-Si,” Acta Metallurgica 18: 261263, February 1970.Google Scholar
Turnbull, D. and Cohen, M. H., “On the Free-Volume Model of the Liquid-Glass Transition,” Journal of Chemical Physics, 52 (6): 30383041, March 1970.Google Scholar
Bagley, B. G. and Turnbull, D., “The Preparation and Crystallization Behavior of Amorphous Nickel-Phosphorus Thin Films,” Acta Metallurgica, 18: 857862, August 1970.Google Scholar
deNeufville, J. P., Drummond, C. H. III and Turnbull, D., “The Effect of Excess Ge on the Viscosity of GeO2 ,” Physics and Chemistry of Glasses, 11 (6): 186191, December 1970.Google Scholar
Ehrenreich, H. and Turnbull, D., “Some Views on Amorphous Si and Ge,” Comments on Solid State Physics, Part A2,3: 7581, 1970.Google Scholar
deNeufville, J. P. and Turnbull, D., “Phase Separation in GeO-GeO2 Glasses,” Discussions of the Faraday Society, No. 50, pp. 182190, 1970.Google Scholar
Bennett, C. H, Polk, D. E. Turnbull, D., “Role of Composition in Metallilc Glass FormationActa Metallurgica 19: 12951298, December 1971.Google Scholar
Turnbull, D., “The Liquid State,” Solidification, Metals Park. Ohio: American Society of Metals, pp. 122, 1971.Google Scholar
Polk, D. E. and Turnbull, D., “Flow of Melt and Glass Forms of Metallic Alloys,” Acta Metallurgica, 20: 493498, April 1972.Google Scholar
Turnbull, D. and Polk, D. E., “Structure of Amorphous Semiconductors,” Journal of Non-Crystalline Solids, 8–10: 1935, 1972.Google Scholar
Kim, K. S. and Turnbull, D., “Crystallization of Amorphous Selenium Films: I. Morphology and Kinetics,” Journal of Applied Physics, 44 (12): 52375244, December 1973.CrossRefGoogle Scholar
Pan, D. and Turnbull, D., “Magnetic Properties of Amorphous Co-P Alloys,” Journal of Applied Physics, 45 (3): 14061412, March 1974.Google Scholar
Spaepen, F. and Turnbull, D., “A Mechanism for the Flow and Fracture of Metallic Glasses,” Scripta Metallurgica, 8 (5): 563568, 1974.Google Scholar
Pan, D. and Turnbull, D., “Magnetic Properties of Amorphous Ni-P Alloys,” American Institute of Physics Conference Proceedings No 18, Magnetism and Magnetic Materials – 1973, 19th Annual Conference, Boston, pp. 646650, New York: American Institute of Physics, 1974.Google Scholar
Turnbull, D., “Amorphous Solid Formation and Interstitial Solution Behavior in Metallic Alloy Systems,” [Structures Metalliques Desordonnees (Strasbourg, 1973)], Journal de Physique, 35: C4.14.10, 1974.Google Scholar
Kim, K. S. and Turnbull, D., “Crystallization of Amorphous Selenium Films: II. Photo and Impurity Effects,” Journal of Applied Physics, 45 (8): 34473452, August 1974.Google Scholar
Drummond, C. H. III and Turnbull, D., “Phase Separation in Ge-GeO2 Glasses,” Journal of Non-Crystalline Solids, 7: 1926, 1975.Google Scholar
Chou, C. P. and Turnbull, D., “Transformation Behavior of Pd-Au-Si Metallic Glasses,” Journal of Non-Crystalline Solids, 17 (2): 169188, March 1975.Google Scholar
Turnbull, D. and Bagley, B.G., “Transitions in Viscous Liquids and Glasses,” Treatise on Solid State Chemistry, ed. Hannay, N. B.,Vol.5, pp. 513554, New York: Plenum Press, 1975.Google Scholar
Turnbull, D., “Structure and Properties of Glassy Metals,” Journal of Electronic Materials, 4 (5): 771781, 1975.Google Scholar
Marcus, M. and Turnbull, D., “On the Correlation Between Glass-Forming Tendency and Liquidus Temperature in Metallic Alloys,”Material Science and Engineering, 23:211214, 1976.Google Scholar
Turnbull, D., “Relation of Crystallization Behavior to Structure in Amorphous Systems,” Annals of the New York Academy of Sciences, 279: 185, October 1976.Google Scholar
Spaepen, F. and Turnbull, D., “Formation of Metallic Glasses,” Rapidly Quenched Metals, ed. Grant, N. J. and Giessen, B. C., Second International Conference, pp. 205229, Cambridge, MA: M.I.T. press, 1976.Google Scholar
Turnbull, D., “Formation and Transformation Behavior of Amorphous Solids,” Physics of Structurally Disordered Solids, ed. Mitra, S. S., Proceedings of the NATO Advanced Study Institute on the Physics of Structurally Disordered Solids, 1974, pp. 15, New York: Plenum Press, 1976.Google Scholar
Gross, G., Stephens, R. B. and Turnbull, D., “On the Crystallization of Amorphous Selenium Films: Thermal Effects and Photoeffects,” Journal of Applied Physics, 48 (3): 11391148, March 1977.CrossRefGoogle Scholar
Turnbull, D., “On the Gram-Atomic Volumes of Metal-Metalloid Glass Forming Alloys,” Scripta Metallurgica, 11: 11311136, 1977.Google Scholar
Spaepen, F. and Turnbull, D., “Atomic Transport and Transformation Behavior,” Metallic Glasses, pp. 114127, Metals Park, Ohio: American Society of Metals, 1978.Google Scholar
Chaudhari, P. and Turnbull, D., “Structure and Properties of Metallic Glasses,” Science, 199: 1121, January 1978.Google Scholar
Lin, C. H., Bevk, J. and Turnbull, D., “Effect of Structural Relaxation on the Electrical Resistivity of Pd8 2−xVxSi18 Amorphous Alloys,” Solid State Communications, 29: 641644, 1979.Google Scholar
Rosenblum, M. P. and Turnbull, D., “Bias Sputter Depositon of Pd-Au-Si and Pd-Si: Composition and Thermal Behavior,” Journal of Non-Crystalline Solids, 37: 4551, 1980.Google Scholar
Chaudhari, P., Giessen, B. C. and Turnbull, D., “Metallic Glasses,” Scientific American, 242 (4): 98117, April 1980.Google Scholar
Rosenblum, M. P., Spaepen, F. and Turnbull, D., “Diffusion and Structural Relaxation in Compositionally Modulated Amorphous Metal Films,” Applied Physics Letters, 37 (2): 184186, July 1980.Google Scholar
Drehman, A. J. and Turnbull, D., “Solidification Behavior of Undercooled Pd83Si17 and Pd82Si18 Liquid Droplets,” Scripta Metallurgica, 15 (5): 543548, 1981.Google Scholar
Turnbull, D., “Metastable Structures in Metallurgy,” The 1980 Campbell Memorial Lecture, The American Society for Metals, Metallurgical Transactions A, 12A: 695708, May 1981.Google Scholar
Turnbull, D., “On the Atomic Volume of Metal-Metalloid Crystalline Alloys”, Scripta Metallurgica, 15: 10391042, 1981.Google Scholar
Turnbull, D., “On the Melting of Amorphous Ge and Si,” Metastablec Materials Formation by Ion Implantation, Materials Research Society Symposia Proceedings, Vol 7, ed. Picraux, S. T. and Choyke, W. J., pp. 103108, Elsevier Publishing Co., Inc., 1982.Google Scholar
Drehman, A. J. and Turnbull, D., “Crystal Nucleation in Pd-Si Alloys,” Materials Processing in the Reduced Gravity Environment of Space, ed. Rindone, G. E., pp. 8185, Amsterdam: North Holland, 1982.Google Scholar
Drehman, A. J., Greer, A. L. and Turnbull, D., “Bulk Formation of a Metallic Glass: Pd40Ni40P20 ,” Applied Physics Letters 41 (8): 716717, October 1982.Google Scholar
Turnbull, D., “Thermodynamics of Equilibrium and Non-Equilibrium Crystallization of Ge and Si,” Journal de Physique, Supplement to No. 10, 43, C1.259–C1.269, October 1982.Google Scholar
Turnbull, D., “Metastable Solid Phases,” McGraw-Hill Yearbook of Science and Technology, pp. 310312, New York: McGraw-Hill Book Company, 1982/1983.Google Scholar
Donovan, E. P., Spaepen, F., Turnbull, D., Poate, J. M. and Jacobson, D. C., “Heat of Crystallization and Melting Point of Amorphous Silicon,” Applied Physics Letters, 42 (8): 698700, April 1983.CrossRefGoogle Scholar
Turnbull, D., “Survey of the Thermodynamics and Kinetics of Crystallization of Si and Ge,” Laser-Solid Interactions and Transient Thermal Processing of Materials, Materials Research Society Symposia Proceedings, Vol.13, ed. by Narayan, J., Brown, W. L., and Lemons, R. A., New York: Elsevier Science Publishing Co., Inc., 1983, pp. 131134.Google Scholar
Lin, C. J., Spaepen, F. and Turnbull, D., “Picosecond Pulsed Laser-Induced Melting and Glass Formation in Metals,” Journal of Non-Crystalline Solids, 61/62: 767772, 1984.Google Scholar
Donovan, E. P., Spaepen, F., Turnbull, D., Poate, J. M., and Jacobson, D. C., “Thermodynamics and Kinetics of Crystallization of Amorphous Si and Ge Produced by Ion Implantation,” Materials Research Society Symposia Proceedings, Vol.27, ed. Hubler, G. K., Holland, O. W., Clayton, C. R., and White, C. W., pp. 211216, North-Holland Publishing Company, 1984.Google Scholar
Spaepen, F. and Turnbull, D., “Metallic Glasses,” Annual Review of Physical Chemistry, 35: 241–63, 1984.Google Scholar
Turnbull, D., “Kinetics and Metastable Structure Formation in Rapid Solidification Processing,” Proceedings of Second Israel Materials Engineering Conference, Ben Gurion University, Beersheva, ed. Grill, A. and Rokhlin, S. I., pp. 110 (1984).Google Scholar
Kui, H. W., Greer, A. L. and Turnbull, D., “Formation of Bulk Metallic Glass by Fluxing,” Applied Physics Letters, 45 (6): 615616, September 1984.Google Scholar
Donovan, E. P., Spaepen, F., Turnbull, D., Poate, J. M. and Jacobson, D. C., “Calorimetric Studies of Crystallization and Relaxation of Amorphous Si and Ge Prepared by Ion Implantation,” Journal of Applied Physics, 57 (6): 17951804, 15 March 1985.Google Scholar
Devaud, G. and Turnbull, D., “Undercooling of Molten Silicon,” Applied Physics Letters, 46 (9): 844845, 1 May 1985.Google Scholar
Turnbull, D., “Dependence of Crystallization Rate on Amorphous Structure,” Proceedings of the International Conference on the Theory of the Structures of Non-Crystalline Solids, Institute for Amorphous Studies Bloomfield Hills, Michigan, June 3–6, 1985, North-Holland Publishing Co. Google Scholar
Turnbull, D., A Commentary on the Recognition and Characterization of the Metallic Glass State,” Proceedings, EPRI-Acta Met. Workshop on Amorphous Metals and Semiconductors, Coronado, California, May 13–17, 1985.Google Scholar
Kui, H. W. and Turnbull, D., “The Melting of Ni40Pd40P20 Glass,” Applied Physics Letters, 47 (8): 796797, 15 October 1985.Google Scholar
Fisher, J. C., Hollomon, J. H. and Turnbull, D., “Absolute Reaction Rate Theory for Diffusion in Metals,” Metals Technology, Technical Publication 2344, February 1948.Google Scholar
Hoffman, R. E. and Turnbull, D., “Lattice and Grain Boundary Self-Diffusion in Silver,” Journal of Applied Physics, 22 (5): 634639, May 1951.Google Scholar
Turnbull, D., “Grain Boundary and Surface Diffusion,” Atomic Movements, American Society of Metals Special Volume, pp. 129152, 1951.Google Scholar
Hoffman, R. E. and Turnbull, D., “Effect of Impurities on the Self-Diffusion of Silver,” Journal of Applied Physics, 23 (12): 1409, December 1952.Google Scholar
Turnbull, D. and Hoffman, R. E., “The Effect of Relative Crystal and Boundary Orientations on Grain Boundary Diffusion Rates,” Acta Metallurgica, 2: 419426, May 1954.Google Scholar
Turnbull, D., “Diffusion Short Circuits and Their Role in Precipitation,” Defects in Crystalline Solids, Report of Physical Society Bristol Conference, pp. 203211, 1954.Google Scholar
Turnbull, D., “Role of Structural Impurities in Phase Transformations,” Impurities and Imperfections, American Society of Metals, pp.121144, 1955.Google Scholar
Hoffman, R. E., Turnbull, D. and Hart, E. W., “Self-Diffusion in Dilute Binary Solid Solutions,” Acta Metallurgica, 3 (5): 417424, September 1955.Google Scholar
Frank, F. C. and Turnbull, D., “Mechanism of Diffusion of Copper in Germaium,” Physical Review, 104 (3): 617618, November 1956.Google Scholar
Hart, E. W., Hoffman, R. E. and Turnbull, D., “Self-Diffusion in Dilute Binary Solid Solutions - II,” Acta Metallurgica, 5: 7476, February 1957.Google Scholar
Turnbull, D. and Hoffman, R. E., “A Correlation of Data on Diffusion of Solutes in Face-Centered Cubic Metals,” Acta Metallurgica, 7:407410, June 1959.Google Scholar
DeSorbo, W. and Turnbull, D., “Quenching of Imperfections in Aluminum,” Acta Metallurgica 7: 8385, February 1959.Google Scholar
DeSorbo, W. and Turnbull, D., “Kinetics of Vacancy Motion in High-Purity Aluminum,” Physical Review, 115 (3): 560563, August 1959.Google Scholar
Anthony, T. R. and Turnbull, D., “On the Theory of Interstitial Solutions of the Noble Metals in Lead, Tin, Thallium, Indium, and Cadmium,” Applied Physical Letters, 8 (5): 120121, March 1966.Google Scholar
Dyson, B. F., Anthony, T. and Turnbull, D., “Interstitial Diffusion of Copper and Silver in Lead,” Journal of Applied Physics, 37 (6): 23702374, May 1966.Google Scholar
Anthony, T. R., Dynson, B. F. and Turnbull, D., “Pressure Dependence of Interstitial-Substitutional Dissociative Diffusion,” Journal of Applied Physics, 37: 29252926, 1966.CrossRefGoogle Scholar
Turnbull, D., “Interstitial Solutions of Noble Metals in Metals and Semiconductors,” Proceedings of the Memorial Lecture Meeting on the Tenth Anniversary of the Foundation of National Research Institute of Metals, ed. Editorial Committee of the Proceedings, 1966.Google Scholar
Anthony, T. R. and Turnbull, D., “Interstitial Diffusion of Gold and Silver in Indium,” The Physical Review, 151 (2): 495498, November 1966.Google Scholar
Dyson, B. F., Anthony, T. R. and Turnbull, D., “Interstitial Diffusion of Copper in Tin,” Journal of Applied Physics, 38 (8): 3408, July 1967.Google Scholar
Anthony, T. R., Dyson, B. F. and Turnbull, D., “Diffusion of Gold and Silver in Thallium,” Journal of Applied Physics, 39 (3): 13911395, February 1968.Google Scholar
Anthony, T. R., Miller, J. W. and Turnbull, D., “Interstitial Dissolution and Diffusion in Metallic Systems,” Scripta Metallurgica, 3: 183190, 1969.Google Scholar
Baughman, R. H. and Turnbull, D., “Vacancy Formation Parameters in Organic Crystals,” Journal of Physical Chemistry Solids, 32: 1375–;1394, 1971.Google Scholar
Baughman, R. and Turnbull, D., “Self-Diffusion in Crystalline Hexamethylethane and Cyclooctane,” Journal of Physical Chemistry Solids 33: 121128, 1972.Google Scholar
Owens, C. W. and Turnbull, D., “Diffusivity of Sodium in Lead,” Journal of Applied Physics, 43 (10): 39333936, October 1972.Google Scholar
Turnbull, D., “Amorphous Solid Formation and Interstitial Solution Behavior in Metallic Alloy Systems,” [Structures Metalliques Desordonnees (Strasbourg, 1973)], Journal de Physique, 35: C4.1–4.10, 1974.Google Scholar
Akutagawa, W., Turnbull, D., Chu, W. K. and Mayer, J. W., “Channeling and Electrical Investigations of Au Doped CdTe,” Solid State Communcations, 15: 19191922, 1974.Google Scholar
Warburton, W. K. and Turnbull, D., “‘Fast’ Diffusion in Alloys,” Thin Solid Films, 25: 7176, 1975.Google Scholar
Akutagawa, W., Turnbull, D., Chu, W. K. and Mayer, J. W., “Solubility and lattice Location of Au in CdTe by Backscattering Techniques,” Journal of Physical Chemistry Solids, 36: 521528, 1975.Google Scholar
Warburton, W. K. and Turnbull, D., “Fast Diffusion in Metals,” Diffusion in Solids: Recent Developments, ed. Nowick, A. S. and Burton, J. J., pp. 171229, New York: Academic press, 1975.Google Scholar
Bahk, S., Ashby, M. F., Bevk, J. and Turnbull, D., “Effect of BeO Inclusions on the Rate of Sintering of Cu Wires,” Sintering and Catalysis ed. Kuczynski, G. C., pp. 269278, New York: Plenum Publishing Corp., 1976.Google Scholar
Cohen, B. M., Turnbull, D. and Warburton, W. K., “Multiple Point-Defect Formation in Pb(Au) Alloys: Observation by Solute Resistivity Measurements,” Physical Review B, 16 (6): 24912503, September 1977.Google Scholar
Cohen, B. M. and Turnbull, D., “Kinetics of Precipitation of Ag from Pb(Ag) Alloys,” Acta Metallurgica, 26: 113116, 1978.Google Scholar
Spaepen, F. and Turnbull, D., “Atomic Transport and Transformation Behavior,” Metallic Glasses, pp. 114127, Metals Park, Ohio: American Society of Metals, 1978.Google Scholar
Hu, C. K., Berko, S., Gruzalski, G. R. and Turnbull, D., “Evidence for Microporosity and Dislocations in Pb(Cd) Alloys from Positron Annihilation Studies,” Solid State Communications, 31: 6568, 1979.Google Scholar
Yavari, A. R. and Turnbull, D., “Dependence of Yield Strength of Pb Single Crystals at 77K on Au Concentration,” Scripta Metallurgica, 14: 8387, 1980.Google Scholar
Yavari, A. R. and Turnbull, D., “Effect of Ag Content on the Yield Strength of Pb(Ag) Alloys at 77KM,” Scripta Metallurgica, 14: 349355, 1980.Google Scholar
Rosenblum, M. P., Spaepen, F. and Turnbull, D., “Diffusion and Structural Relaxation in Compositionally Modulated Amorphous Metal Films,” Applied Physics Letters, 37 (2): 184186, July 1980.Google Scholar
Ashby, M. F., Bahk, S., Bevk, J. and Turnbull, D., “The Influence of a Dispersion of Particles on the Sintering of Metal Powders and Wires,” Progress in Materials Science, 25: 134, 1980.Google Scholar
Yavari, A. R. and Turnbull, D., “Effect of Compositon and Thermal Treatment on the Yield Stress and Resisitivity of Pb(Au) Alloys,” Acta Metallurgica, 30: 11711176, 1982.Google Scholar
Butrymowicz, D. B., Newbury, D. E., Turnbull, D. and Cahn, J. W., “Diffusion-Induced Grain Boundary Migration in the Au-Ag System,” Scripta Metallurgica, 18: 10051010, 1984.Google Scholar
Nygren, E., Aziz, M. J., Turnbull, D., Poate, J. M., Jacobson, D. C. and Hull, R., “Pressure Dependence of Arsenic Diffusivity in Silicon,” Applied Physics Letters, 47 (2): 105107, 15 July 1985.Google Scholar
Aziz, M. J., Nygren, E., Christie, W. H., White, C. W. and Turnbull, D., “Effect of Pressure on Self Diffusion in Crystalline Silicon,” Materials Research Symposium Proceedings 36: 101104, 1985.Google Scholar
Turkalo, A. M. and Turnbull, D., “Some Observations on the Rate of Secondary Recrystallization in High Purity Copper,” Journal of Metals, Transactions Section, 185: 663664, September 1949.Google Scholar
Fisher, J. C., Hollomon, J. H. and Turnbull, D., “Kinetics of the Austenite-Martensite Transformation,” Journal of Metals Transactions Section, 185: 691700, October 1949.Google Scholar
Turnbull, D., “Principles of Solidification,” Thermodynamics in Physical Metallurgy, Cleveland: American Society for Metals, pp. 282306, February 1950.Google Scholar
Turnbull, D., “Theory of Grain Boundary Migration Rates,” Journal of Metals, IIl (8): 17, and Transactions AIME, 191: 1–7, August 1951.Google Scholar
Burke, J. E. and Turnbull, D., “Recrystallization and Grain Growth,” Progress in Metal Physics ed. Chalmers, B., pp. 220292, London: Pergamon Press, 1952.Google Scholar
Fisher, J. C. and Turnbull, D., “Influence of Stress on Martensite Nucleation,” Acta Metallurgica, 1: 310314, May 1953.Google Scholar
Fisher, J. C. and Turnbull, D., “Calculation of Martensite Nucleus Energy Using the Reaction-Path Model,” Journal of Metals, 5: 12, July 1953.Google Scholar
Turnbull, D., “The Kinetics of Precipitation of Barium Sulfate from Aqueous Solution,” Acta Metallurgica, 1:684–591, November 1953.Google Scholar
Cech, R. E. and Turnbull, D., “Magnetic Transformation of Iron in Copper Matrix at Low Temperatures,” Journal of Metals, Transactions AIME, pp. 4546, January 1954.Google Scholar
Turnbull, D. and Treaftis, H. N., “Kinetics of Precipitation of Tin from Lead-Tin Solid Solutions,” Acta Metallurgica, 3 (1): 4354, January 1955.Google Scholar
Turnbull, D., “Theory of Cellular Precipitation,” Acta Metallurgica, 3 (1): 5563, January 1955.Google Scholar
Newkirk, J. B. and Turnbull, D., “Nucleation of Ammonium Iodide Crystals from Aqueous Solutions,” Journal of Applied Physics, 26(5): 579583, May 1955.Google Scholar
Cech, R. E. and Turnbull, D., “Heterogeneous Nucleation of the Martensite Transformation,” Journal of Metals, pp. 19, February 1956.Google Scholar
Hillig, W. B. and Turnbull, D., “Theory of Crystal Growth in Undercooled Pure Liquids,” Journal of Chemical Physics, 24 (4): 914, April 1956.Google Scholar
DeSorbo, W. and Turnbull, D., “Kinetics of Precipitation in Small Lead-Tin Spheres,” Acta Metallurgica, 4: 495509, September 1956.CrossRefGoogle Scholar
Turnbull, D., “Phase Changes,” Solid State Physics, III: 225306, 1956.Google Scholar
Turnbull, D., “Possible Role of Inclusions in the Formation of Crystal Reorientation Nuclei,” Acta Metallurgica, 5: 502–506, September 1957.Google Scholar
Turnbull, D. and Treaftis, H. N., “On the Rate of Formation of Guinier-Preston Zones in Al-Ag Alloys,” Acta Metallurgica, 5 (9): 534536, 1957.Google Scholar
May, J. E. and Turnbull, D., “Secondary Recrystallization in Silicon Iron,” Transactions of the Metallurgical Society of AIME, 212: 769781, December 1958.Google Scholar
DeSorbo, W., Treaftis, H. N. and Turnbull, D., “Rate of Clustering in Al-Cu Alloys at Low Temperatures,” Acta Metallurgica, 6: 401413, June 1958.Google Scholar
Rosenbaum, H. S. and Turnbull, D., “On the Precipitation of Silicon Out of a Supersaturated Aluminum-Silicon Solid Solution,” Acta Metallurgica, 6: 653659, October 1958.Google Scholar
Turnbull, D. and Treaftis, H. N., “Micrographic Investigation of Precipitation in Pb-Sn Alloys,” Transactions of the Metallurgical Society of AIME, 212: 3339, February 1958.Google Scholar
Cech, R. E. and Turnbull, D., “Shock-Induced Martensitic Transformation,” Transactions of the Metallurgical Society of AIME, 212: 395397, June 1958.Google Scholar
Turnbull, D., “‘International Conferences on Crystal Growth’ – A Review Article,” Physics Today, 12 (1): 1620, January 1959.Google Scholar
May, J. E. and Turnbull, D., “Effect of Impurities on the Temperature Dependence of the (110) [001] Texture in Silicon-Iron,” Journal of Applied Physics Supplement, 30 (4): 210S212S, April 1959.Google Scholar
Rosenbaum, H. S. and Turnbull, D., “Metallographic Investigation of Precipitation of Silicon from Aluminum,” Acta Metallurgica, 7: 664674, October 1959.Google Scholar
Rosenbaum, H. S., Turnbull, D. and Alessandrini, E., “On the Orientation of Silicon Precipitating from an Al-Rich Solid Solution,” Acta Metallurgica, 7(10): 678679, 1959.Google Scholar
Ehrlich, G. and Turnbull, D., “Surface Structure and Chemical Interaction,” Physical Metallurgy of Stress Corrosion Fracture, ed. Rhodin, T. N., pp. 4748, New York: Interscience Publishers, 1959.Google Scholar
Turnbull, D., Rosenbaum, H. S. and Treaftis, H. N., “Kinetics of Clustering in Some Aluminum Alloys,” Acta Metallurgica, 8: 277295, May 1960.Google Scholar
Turnbull, D. and Cormia, R. L., “Kinetics of Later Stages of Clustering in Al-Cu Alloy,” Acta Metallurgica, 8: 747750, November 1960.Google Scholar
Ainslie, N. G., Phillips, V. A. and Turnbull, D., “Sulfur Segregation at Iron Grain Boundaries – II,” Acta Metallurgica, 8: 528538, August 1960.Google Scholar
Ainslie, N. G., MacKenzie, J. E. and Turnbull, D., “Melting Kinetics of Quartz and Cristobalite,” Journal of Physical Chemistry, 65: 17181724, October 1961.Google Scholar
Ainslie, N. G., Morelock, C. R. and Turnbull, D., “Devitrification Kinetics of Fused Silica,” Symposium on Nucleation and Crystallization in Glasses and Melts, ed. Reser, M. K., Smith, G. and Insley, H., American Ceramic Society, pp. 97107, 1962.Google Scholar
Turnbull, D., Definitions of “Nucleation,” “Nucleation and Growth in Recrystallization,” “Nucleation Phenomena in Liquids,” “Precipitation in Alloys” and “Transformation, Diffusionless,” Encyclopaedic Dictionary of Physics, Oxford: Pergamon Press, 1962.Google Scholar
Cormia, R. L., MacKenzie, J. D. and Turnbull, D., “Kinetics of Melting and Crystallization of Phosphorus Pentoxide,” Journal of Applied Physics, 34 (8): 2239–2244, August 1963.Google Scholar
Servi, I. S. and Turnbull, D., “Thermodynamics and Kinetics of Precipitation in the Copper-Cobalt System,” Acta Metallurgica, 14: 161–169, February 1966.Google Scholar
Uhlmann, D. R., Hays, J. F. and Turnbull, D., “The Effect of High Pressure on Crystallization Kinetics with Special Reference to Fused Silica,” Physics and Chemistry of Glasses 7 (5): 159168, October 1966.Google Scholar
Tu, K. N. and Turnbull, D., “Morphology of Cellular Precipitation of Tin from Lead-Tin Bicrystals,” Acta Metallurgica, 15: 369376, February 1967.Google Scholar
Uhlmann, D. R., Hays, J. F. and Turnbull, D., “The Effect of High Pressure on B2O3: Crystallizaton, Densification and the Crystallization Anomaly,” Physics and Chemistry of Glasses 8 (1): 1–10, February 1967.Google Scholar
Tu, K. N. and Turnbull, D., “Morphology of Cellular Precipitation of Tin from Lead-Tin Bicrystals – II,” Acta Metallurgica, 15: 1317–1323, August 1967.Google Scholar
Tu, K. N. and Turnbull, D., “Analysis of Kinetics of Boundary Diffusion Limited Cellular Precipitation,” Scripta Metallurgica, 1 (3): 173180, 1967.Google Scholar
Tu, K. N. and Turnbull, D. Nucleation in Solids: (A) Brief Survey; (B) Cellular Precipitation,” Mechanism of Phase Transformations in Crystalline Solids, pp. 3236, Institute of Metals Monograph, 33, London, 1969.Google Scholar
Tu, K. N. and Turnbull, D., “Morphology of Structure of Tin Lamellae Formed by Cellular Precipitation,” Acta Metallurgica, 17: 1263–1279, October 1969.Google Scholar
Tu, K. N. and Turnbull, D., “Direct Observation of Twinning in Tin Lamellae,” Acta Metallurgica, 18: 915929, August 1970.Google Scholar
Turnbull, D. and Tu, K. N., “The Cellular and Pearlitic Reactions,” Phase Transformations, pp.487495, Metals Park, Ohio: American Society for Metals, 1970.Google Scholar
Tu, K. N. and Turnbull, D., “Morphology and Kinetics of the Cellular Dissolution of the Pb-Sn Alloy,” Metallurgical Transactions, 2: 25092515, September 1971.Google Scholar
Rossolimo, A. N. and Turnbull, D., “Kinetics and Morphology of Precipitation of AuPb3 from Pb(Au) Solid Solution,” Acta Metallurgica, 21: 2134, January 1973.Google Scholar
Kim, K. S. and Turnbull, D., “Crystallization of Amorphous Selenium Films: I. Morphology and Kinetics,” Journal of Applied Physics, 44 (12): 52375244, December 1973.Google Scholar
Kim, K. S. and Turnbull, D., “Crystallization of Amorphous Selenium Films: II. Photo and Impurity Effects,” Journal of Applied Physics, 45 (8): 34473452, August 1974.Google Scholar
Gross, G., Stephens, R. B. and Turnbull, D., “On the Crystallization of Amorphous Selenium Films: Thermal Effects and Photoeffects,” Journal of Applied Physics, 48 (3): 11391148, March 1977.Google Scholar
Lo, K., Bevk, J. and Turnbull, D., “Critical Currents in Liquid-Quenched Nb3AI,” Journal of Applied Physics, 48 (6): 25972600, June 1977.Google Scholar
Spaepen, F. and Turnbull, D., “Kinetics of Motion of Crystal-Melt Interfaces,” Laser Solid Interactions and Laser Processing, American Institute of Physics Conference Proceedings #50, 1978, eds. Ferris, S. D., Leamy, H. J., Poate, J. M., p. 73, New York: American Institute of Physics, 1979.Google Scholar
Fratello, V. J., Hays, J. F. and Turnbull, D., “Crystallization Kinetics of SiO2 at High Pressures,” High Pressure Science and Technology, Vol. 1, ed. Timmerhaus, K. D. and Barber, M. S., pp. 977980 New York: Plenum Publishing Corp., 1979.Google Scholar
Fratello, V. J., Hays, J. F. and Turnbull, D., “Dependence of Growth Rate of Quartz in Fused Silica on pressure and Impurity Content,” Journal of Applied Physics, 51 (9): 47184728, September 1980.Google Scholar
Fratello, V. J., Hays, J. F., Spaepen, F. and Turnbull, D., “The Mechanism of Growth of Quartz Crystals Into Fused Silica,” Journal of Applied Physics, 51 (12): 61606164, December 1980.Google Scholar
Turnbull, D., “Comments on ‘The Mechanisms of Laser Annealing’,” Proceedings of Europhysics Study Conference on Laser Annealing in Solids, Mons, Belgium, 1979, Journal de Physique, 41: C4.109–C4.110, May 1980.Google Scholar
Turnbull, D., “Citation Classic,” Engineering, Technology and Applied Sciences, 12 (36): 28, September 1981. [On “Theory of Cellular Precipitation,” Acta Metallurgica, 3: 55–63, January 1955.]Google Scholar
Turnbull, D., “Metastable Structures in Metallurgy,” The 1980 Campbell Memorial Lecture, The American Society for Metals, Metallurgical Transactions A, 12A: 695708, May 1981.Google Scholar
Spaepen, F. and Turnbull, D., “Crystallization Processes,” Laser Annealing of Semiconductors, ed. Poate, J. M. and Mayer, J. W., pp. 1542, New York: Academic Press, 1982.Google Scholar
Turnbull, D., “On the Melting of Amorphous Ge and Si,” Metastable Materials Formation by Ion Implantation, Materials Research Society Symposia Proceedings, Vol 7, ed. Picraux, S. T. and Choyke, W. J., pp. 103108, Elsevier Publishing Co., Inc., 1982.Google Scholar
Coriell, S. R. and Turnbull, D., “Relative Roles of Heat Transport and Interface Rearrangement Rates in the Rapid Growth of Crystals in Undercooled Metals,” Acta Metallurgica 30: 21352139, 1982.Google Scholar
Turnbull, D., “Thermodynamics of Equilibrium and Non-Equilibrium Crystallization of Ge and Si,” Journal de Physique, Supplement to No. 10, 43, C1.259–C1.269, October 1982.Google Scholar
Turnbull, D., “Metastable Solid Phases,” McGraw-Hill Yearbook of Science and Technology, pp. 310312, New York: McGraw-Hill Book Company, 1982/1983.Google Scholar
Turnbull, D., “Thermodynamics and Kinetics of Laser-Induced Structure Changes,” Physical Processes in Laser-Materials Interactions, ed. Bertolotti, M., NATO Advanced Study Institute, pp. 117142, New York: Plenum Publishing Corp., 1983.Google Scholar
Donovan, E. P., Spaepen, F., Turnbull, D., Poate, J. M. and Jacobson, D. C., “Heat of Crystallization and Melting Point of Amorphous Silicon,” Applied Physics Letters, 42 (8): 698700, April 1983.Google Scholar
Turnbull, D., “Survey of the Thermodynamics and Kinetics of Crystallization of Si and Ge,” Laser-Solid Interactions and Transient Thermal Processing of Materials, Materials Research Society Symposia Proceedings, Vol.13, ed. by Narayan, J., Brown, W. L., and Lemons, R. A., New York: Elsevier Science Publishing Co., Inc., 1983, pp. 131134.Google Scholar
Lin, C. J., Spaepen, F. and Turnbull, D., “Picosecond Pulsed Laser-Induced Melting and Glass Formation in Metals,” Journal of Non-Crystalline Solids, 61/62: 767772, 1984.Google Scholar
Donovan, E. P., Spaepen, F., Turnbull, D., Poate, J. M., and Jacobson, D. C., “Thermodynamics and Kinetics of Crystallization of Amorphous Si and Ge Produced by Ion Implantation,” Materials Research Society Symposia Proceedings, Vol. 27, ed. Hubler, G. K., Holland, O. W., Clayton, C. R., and White, C. W., pp. 211216, North-Holland Publishing Company, 1984.Google Scholar
Turnbull, D., “Kinetics and Metastable Structure Formation in Rapid Solidification Processing,” Proceedings of Second Israel Materials Engineering Conference, Ben Gurion University, Beersheva, ed. Grill, A. and Rokhlin, S. I., pp. 110 (1984).Google Scholar
Aziz, M. J., Nygren, E., Hays, J. F. and Turnbull, D., “Crystal Growth Kinetics of Boron Oxide Under Pressure,” Journal of Applied Physics, 56 (6): 22332242, 15 March 1985.Google Scholar
Donovan, E. P., Spaepen, F., Turnbull, D., Poate, J. M. and Jacobson, D. C., “Calorimetric Studies of Crystallization and Relaxation of Amorphous Si and Ge Prepared by Ion Implantation,” Journal of Applied Physics, 57 (6): 17951804, 15 March 1985.Google Scholar
Nygren, E., Aziz, M. J., Turnbull, D., Poate, J. M., Jacobson, D. C. and Hull, R., “The Effect of Pressure on the Solid Phase Epitaxial Regrowth Rate of Si,” Applied Physics Letters, 47 (3): 232233, 1 August 1985.Google Scholar
Turnbull, D., “Dependence of Crystallization Rate on Amorphous Structure,” Proceedings of the International Conference on the Theory of the Structures of Non-Crystalline Solids, Institute for Amorphous Studies, Bloomfield Hills, Michigan, June 3–6, 1985, North-Holland Publishing Co. Google Scholar
Clemente, G., Habbal, F., Turnbull, D., Bevk, J., “High-Magnetic Field Transport Properties of Liquid Quenched Nb3A1 and Nb3AI(Si,Ge) Superconducting Compounds,” Applied Physics Letters, 47 (6): 640642, 15 September 1985.Google Scholar
Turnbull, D. and Phipps, T. E., “Evidence of a Periodic Deviation from the Schottky Line – II,” Physical Review, 56: 663667, October 1939.Google Scholar
Maron, S. H. and Turnbull, D., “Activity Coefficients of Gases: Calculation from the Beattie-Bridgeman Equation of State,” Industrial and Engineering Chemistry, 33 (1): 6972, January 1941.Google Scholar
Maron, S. H. and Turnbull, D., “Generalized Equation for Activity Coefficients of Gases,” Industrial and Engineering Chemistry, 33 (2): 246248, February 1941.Google Scholar
Maron, S. H. and Turnbull, D., “Calculating Beattie-Bridgeman Constants from Critical Data,” Industrial and Engineering Chemistry, 33 (3): 408410, March 1941.Google Scholar
Maron, S. H. and Turnbull, D., “Thermodynamic Properties of Nitrogen at High Pressures as Analytic Functions of Temperature and Pressure,” Journal of American Chemical Society, 64: 4447, January 1942.Google Scholar
Maron, S. H. and Turnbull, D., “Generalized Thermodynamic Properties of Gases at High Pressures,” Industrial and Engineering Chemistry, 34 (5): 544551, May 1942.Google Scholar
Maron, S. H. and Turnbull, D., “Equation of State for Gases at High Pressures Involving Only Critical Constants,” Journal of the American Chemical Society, 64: 21952198, September 1942.Google Scholar
Turnbull, D. and Maron, S. H., “The Ionization Constants of Aci and Nitro Forms of Some Nitroparaffins,” Journal of the American Chemical Society, 65: 212218, February 1943.Google Scholar
Prutton, C. F., Frey, D. R., Turnbull, D., and Dlouhy, G., “Corrosion of Metals by Organic Acids in Hydrocarbon Solvents,” Industrial and Engineering Chemistry, 37 (1): 90100, January 1945.Google Scholar
Lukes, J. J., Prutton, C. F. and Turnbull, D., “Equilibrium Between Solid Ferrous Chloride and Gaseous Hydrogen Sulfide at Intermediate Temperatures,” Journal of the American Chemical Society, 67: 697700, May 1945.Google Scholar
Prutton, C. F., Turnbull, D. and Frey, D. R., “Corrosion of Lead by Oxidizing Agents and Lauric Acid in Hydrocarbon Solvents,” Industrial and Engineering Chemistry, 37: 917924, October 1945.Google Scholar
Prutton, C. F., Turnbull, D. and Dlouhy, G., “Reaction Rate of Hydrogen Chloride and Sulfide with Steel,” Industrial and Engineering Chemistry 37 (11): 10921097, November 1945.Google Scholar
Prutton, C. F., Turnbull, D. and Dlouhy, G., “Mechanism of Action of Organic Chlorine and Suphur Compounds in Extreme-Pressure Lubrication,” Journal of the Institue of Petroleum, 32 (266): 90118, February 1946.Google Scholar
Winn, H., Shelton, J. R., and Turnbull, D., “Role of Carbon in Oxidation of GR-S Vulcanizates,” Industrial and Engineering Chemistry, 38: 10521056, October 1946.Google Scholar
Hartman, P. F., Sellers, H. G. and Turnbull, D., “Effect of Temperature and Solvent Upon the Fate of Carboxyl Groups in the Decomposition of Benzoyl Peroxide,” Journal of the American Chemical Society, 69: 24162419, October 1947.Google Scholar
Turnbull, D. and Frey, D. R., “Rate of Corrosion of Lead by Hydrocarbon Solutions of Organic Acids,” Journal of Physical and Colloid Chemistry, 51 (3): 681704, May 1947.Google Scholar
Prutton, C. F. and Turnbull, D., “Relation Between Corrosion Rates of Copper-Lead Bearing Alloys and Pure Lead in Solutions of Organic Acids in Hydrocarbons,” Journal of Corrosion, 3: 13, 1947.Google Scholar
Maron, S. H., Turnbull, D. and Elder, M. E., “The Electrophoretic Mobility of Type II GR-S Latex,” Journal of the American Chemical Society, 70: 582587, February 1948.Google Scholar
Fullman, R. L. and Turnbull, D., “Physical Metallurgists” or “Review of Physical Metallurgy,” Journal of Metals, 1, March 1949.Google Scholar
Turnbull, D., Kirkaldy, J. S., Hilliard, J. E., and Aaronson, H. I., “On the Teaching of a Graduate Course in Phase Transformations,” Journal of Metals, pp. 2429, September 1975.Google Scholar
Turnbull, D., “Some Thoughts on Directions in Materials Science,” Laser and Electron Beam Processing of Materials, ed. White, C. W. and Peercy, P. S., von Hipple Award Lecture, Materials Research Society Symposium, Cambridge, MA, 1979, pp. 15, New York: Academic Press, 1980.Google Scholar
Turnbull, D., “Book Review,” ISIS, 73: 120, 1982. [The Beginnings of Solid State Physics – A Symposium Organized by Sir N. Mott.]Google Scholar
Turnbull, D., “A Commentary on the Emergence and Evolution of ‘Materials Science’,” Annual Review of Materials Science, 13: 17, 1983.Google Scholar