1 Kaufman, L. and Nesor, H., "Stability Characterization of Refractory Materials Under High Velocity Atmospheric Flight Conditions," AFML-TR-69-84, Pt. I, Vol. I, March 1970, ManLabs Inc., Cambridge, Mass. 2 Bernstein, H. and Baron, J. R., "Stability Characterization of Refractory Materials Under High Velocity Atmospheric Flight Conditions," AFML-TR-69-84, Pt. IV, Vol. II, Dec. 1969, ManLabs Inc., Cambridge, Mass. 3 Scala, S. M., "The Ablation of Graphite in Dissociated Air," Paper 62-154,1962, IAS. 4 Gilbert, L. M., "The Hypersonic Diffusion Controlled Oxidation of Tungsten," Rept. R67SD38, 1967, General Electric Co., King of Prussia, Pa. 5 Welsh, W. E. and Chung, P. M., "A Modified Theory for the Effect of Surface Temperature on the Combustion Rate of Carbon Surfaces in Air," Proceedings of the Heat Transfer and Fluid Mechanics Institute, Stanford University Press, 1963, pp. 146-159. 6 Nachtsheim, P. R., "Multicomponent Diffusion on Chemically Reacting Laminar Boundary Layers," Proceedings of the Heat Transfer and Fluid Mechanics Institute, Stanford University Press, 1967, pp. 58-87. 7 Bartlett, E. P., Kendall, R. M., and Rindal, R. A., "Unified Approximation for Mixture Transport Properties for Multicomponent Boundary Layer Applications," Rept. 66-7, Pt. IV, March 1967, Aerotherm Corp., Palo Alto, Calif. 8 JANAF Thermochemical Data, Dow Chemical Co., Midland, Mich., 1960. 9 Hirchfelder, J. O., Curtiss, C. F., and Bird, R. B., Molecular Theory of Gases and Liquids, Wiley, New York, 1966. 10 Kendall, R. M. and Bartlett, E. P., "Nonsimilar Solution of the Multicomponent Laminar Boundary Layer by an Integral Matrix Method," Rept. 66-7, Pt. Ill, March 1967, Aerotherm Corp., Palo Alto, Calif. 11 Fay, J. A. and Riddell, F. R., "Theory of Stagnation Point Heat Transfer in Dissociated Air," Journal of the Aeronautical Sciences, Vol. 25, No. 2, Feb. 1958, pp. 73-85. 12 Diaconis, N. S., Gorsuch, P. D., and Sheridan, R. A., "The Ablation of Graphite in Dissociated Air, Part 2, Experiment," Paper 62-155, 1962, IAS. 13 Metzger, J. W., Engel, M. J., and Diaconis, N. S., "Oxidation and Sublimation of Graphite in Simulated Re-Entry Environments," AIAA Journal, Vol. 5, No. 3, March 1967, pp. 451-460.
[1]
S. Corrsin,et al.
Further experiments on the flow and heat transfer in a heated turbulent air jet
,
1947
.
[2]
Maurice L. Albertson,et al.
Diffusion of Submerged Jets
,
1948
.
[3]
J. M. Smith,et al.
Heat transfer in the critical region
,
1957
.
[4]
T. Brzustowski.
Chemical and physical limits on vapor‐phase diffusion flames of droplets
,
1965
.
[5]
Geoffrey Ingram Taylor,et al.
The transport of vorticity and heat through fluids in turbulent motion
,
1932
.
[6]
J. Hinze,et al.
Transfer of heat and matter in the turbulent mixing zone of an axially symmetrical jet
,
1949
.
[7]
C. C. Miesse,et al.
Correlation of Experimental Data on the Disintegration of Liquid Jets
,
1955
.
[8]
E. Förthmann.
Über turbulente Strahlausbreitung
,
1934
.
[9]
H. B. Squire,et al.
Round Jets in a General Stream
,
1944
.
[10]
H. Schlichting.
Boundary Layer Theory
,
1955
.
[11]
H. Görtler,et al.
Berechnung von Aufgaben der freien Turbulenz auf Grund eines neuen Näherungsansatzes .
,
1942
.
[12]
L. Rayleigh.
On The Instability Of Jets
,
1878
.
[13]
C. Hendricks,et al.
Source of Uniform-Sized Liquid Droplets
,
1964
.
[14]
Walter Tollmien,et al.
Calculation of Turbulent Expansion Processes
,
1945
.
[15]
P. R. Wieber.
Calculated temperature histories of vaporizing droplets to the critical point
,
1963
.
[16]
Warren M. Rohsenow,et al.
Heat Mass and Momentum Transfer
,
1961
.
[17]
A Haenlein.
Disintegration of a Liquid Jet
,
1932
.