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Taylor–von Neumann–Sedov blast wave

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Taylor–von Neumann–Sedov blast wave (or sometimes referred to as Sedov–von Neumann–Taylor blast wave) refers to a blast wave induced by a strong explosion. The blast wave was described by a self-similar solution independently by G. I. Taylor, John von Neumann and Leonid Sedov during World War II.[1][2]

History

G. I. Taylor was told by the British Ministry of Home Security that it might be possible to produce a bomb in which a very large amount of energy would be released by nuclear fission and asked to report the effect of such weapon. Taylor presented his results in June 27, 1941.[3] Exactly at the same time, in the United States, John von Neumann was working on the same problem and he presented his results on June 30, 1941.[4] It was said that Leonid Sedov was also working on the problem around the same time in the USSR, although Sedov never confirmed any exact dates.[5]

The complete solution was published first by Sedov in 1946.[6] von Neumann published his results in August 1947 in the Los Alamos scientific laboratory report on "Blast wave" (PDF)., although that report was distributed only in 1958.[7] Taylor got clearance to publish his results in 1949 and he published his works in two papers in 1950.[8][9] In the second paper, Taylor calculated the energy of the atomic bomb used in the Trinity (nuclear test) using the similarity, just by looking at the time series of blast wave photographs published by Julian E Mack in 1947.[10]

Mathematical description

Consider a strong explosion (such as nuclear bombs) that releases a large amount of energy in a small volume during a short time interval. This will create a strong spherical shock wave propagating outwards from the explosion center. The self-similar solution tries to describe the flow when the shock wave has moved through a distance that is extremely large when compared to the size of the explosive. At these large distances, the information about the size and duration of the explosion will be forgotten; only the energy released will have influence on how the shock wave evolves. To a very high degree of accuracy, then it can be assumed that the explosion occurred at a point (say the origin ) instantaneously at time .

The shock wave in the self-similar region is assumed to be still very strong such that the pressure behind the shock wave is very large in comparison with the pressure (atmospheric pressure) in front of the shock wave , which can be neglected from the analysis. Although the pressure of the undisturbed gas is negligible, the density of the undisturbed gas cannot neglected since the density jump across strong shock waves are finite as a direct consequence of Rankine–Hugoniot conditions. This approximation is equivalent to setting and the corresponding sound speed , but keeping its density non zero, i.e., .[11]

The only parameters available at our disposal are the energy and the undisturbed gas density . The properties behind the shock wave such as are derivable from those in front of the shock wave. The only non-dimensional combination available from and is

.

The solution is assumed to be a function only of the above variable. The shock wave location will correspond to some value denoted here by , i.e.,

The propagation velocity of the shock wave is

With the approximation described above, Rankine–Hugoniot conditions determines the gas velocity immediately behind the shock front , and for an ideal gas as follows

where is the specific heat ratio. Since is a constant, the density immediately behind the shock wave is not changing with time, whereas and decrease as and , respectively.

Self-similar solution

The gas motion behind the shock wave is governed by Euler equations. For an ideal polytropic gas with spherical symmetry, the equations for the fluid variables such as radial velocity , density and pressure are given by

At , the solutions should approach the values given by the Rankine-Hugoniot conditions defined in the previous section.

The variable pressure can be replaced by the sound speed since pressure can be obtained from the formula . The following non-dimensional self-similar variables are introduced,[12][13]

.

The conditions at the shock front becomes

Substituting the self-similar variables into the governing equations will lead to three ordinary differential equations. Solving these differential equations analytically is laborious, as shown by Sedov in 1946 and von Neumann in 1947. G. I. Taylor integrated these equations numerically to obtain desired results.

The relation between and can be deduced directly from energy conservation. Since the energy associated with the undisturbed gas us neglected by setting , the total energy of the gas within the shock sphere must be equal to . Due to self-similarity, it is clear that non only the total energy within a sphere of radius is constant, but also the total energy within sphere of any radius (in dimensional form, it says that total energy within a sphere of radius that moves outwards with a velocity must be equal to ). The amount of energy that leaves the sphere of radius in time due to the gas velocity is , where is the specific enthalpy of the gas. In that time, the sphere radius is increases dictated by the velocity and the energy of the gas in this extra increased volume is , where is the specific energy of the gas. Equating these expressions and substituting and that is valid for ideal polytropic gas leads to

The continuity and energy equation reduces to

Expressing and as a function of only using the relation obtained earlier and integrating once yields the solution in implicit form,

where

The constant that determines the shock location can be determined from the conservation of energy

to obtain

For air, and .

References

  1. ^ Bluman, G. W., & Cole, J. D. (2012). Similarity methods for differential equations (Vol. 13). Springer Science & Business Media.
  2. ^ Barenblatt, G. I., Barenblatt, G. I., & Isaakovich, B. G. (1996). Scaling, self-similarity, and intermediate asymptotics: dimensional analysis and intermediate asymptotics (Vol. 14). Cambridge University Press.
  3. ^ G. I. Taylor, British Report RC-210, June 27, 1941.
  4. ^ John von Neumann, NDRC, Div. B, Report AM-9, June 30, 1941.
  5. ^ Deakin, M. A. (2011). GI Taylor and the Trinity test. International Journal of Mathematical Education in Science and Technology, 42(8), 1069-1079.
  6. ^ Sedov, L. I. (1946). Propagation of strong shock waves. Journal of Applied Mathematics and Mechanics, 10, 241-250.
  7. ^ J. von Neumann, The point source solution, in Collected Works, Vol. 6, A.H. Taub, ed., Pergamon, New York, 1963, pp. 219–237.
  8. ^ Taylor, G. I. (1950). The formation of a blast wave by a very intense explosion I. Theoretical discussion. Proceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences, 201(1065), 159-174.
  9. ^ Taylor, G. I. (1950). The formation of a blast wave by a very intense explosion.-II. The atomic explosion of 1945. Proceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences, 201(1065), 175-186.
  10. ^ Mack, J. E. (1946). Semi-popular motion-picture record of the Trinity explosion (Vol. 221). Technical Information Division, Oak Ridge Directed Operations.
  11. ^ Zelʹdovich, I. B., & Raĭzer, I. P. (1968). Physics of shock waves and high-temperature hydrodynamic phenomena (Vol. 1). Academic Press. Section 25. pp. 93-101.
  12. ^ Landau, L. D., & Lifshitz, E. M. (1987). Fluid mechanics. Translated from the Russian by JB Sykes and WH Reid. Course of Theoretical Physics, 6. Section 106, pp. 403-407.
  13. ^ Sedov, L. I. (1993). Similarity and dimensional methods in mechanics. CRC press.