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Kinetics of a Network of Vortex Loops in HeII and Theory of Superfluid Turbulence

Kinetics of a Network of Vortex Loops in HeII and Theory of Superfluid Turbulence. Sergey K. Nemirovskii Institute for T hermophysics , Novosibirsk, Russia;. Vortex Tangle in HeII. (K. Schwarz, 1988). Network of cosmic strings (D. Bennet, F. Bouchet,1989 ).

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Kinetics of a Network of Vortex Loops in HeII and Theory of Superfluid Turbulence

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  1. Kinetics of a Network of Vortex Loops in HeII and Theory of Superfluid Turbulence Sergey K. Nemirovskii Institute for Thermophysics, Novosibirsk, Russia;

  2. Vortex Tangle in HeII. (K. Schwarz, 1988)

  3. Network of cosmic strings (D. Bennet, F. Bouchet,1989 )

  4. Tangle of string-like defects in nematic liquid crystal I.Chuang, R. Durrer, N. Turok, B. Yorke, (“Science”, 1991)

  5. Dislocations in solids, C. Deebet al. (2004)

  6. Topological defects in Bose Gas (N. Berloff, B. Svistunov, 2001)

  7. Tangle of vortex filaments obtained in turbulent flow at moderately high Reynolds (Vincent and Meneguzzi 1991).

  8. Reconnection of lines

  9. Reconnection of string-like defects in nematic liquid crystal I.Chuang, R. Durrer, N. Turok, B. Yorke, (“Science”, 1991)

  10. Reconnection results in break down or merging (recombination) of vortex loops

  11. Feynman’s scenario Striking example of very important role of recombination processes is a famous Feynman’s scenario of decay of vortex tangle. Break down of vortex rings leads to a cascade-like process of formation of the smaller and smaller loops. As a result the "flux" of length in space of scales with subsequent reduction of the total length of vortex lines takes place.

  12. Thus, the characteristic time of Kelvin waves dynamics exceeds time of life of the loop by 10³ times (!!!)

  13. Kinetics of loops or Kelvin waves dynamics ? • 1. But this means that the vast majority of loops do not live (as a whole) long enough to perform any essential evolution due to the Kelvin waves dynamics. • 2. Therefore we have to think of the superfluid turbulence as the kinetics of randomly merging and splitting loops rather then smooth (deterministic) motion of the vortex line elements.

  14. Thus the basic approach to study superfluid turbulence should be grounded on consideration of a set of randomly merging and splitting loops. Up to now the numerical results remain the main source of information about this process. The scarcity of analytic investigations is related to the incredible complexity of the problem. Indeed we have to deal with a set of objects which do not have a fixed number of elements, they can be born and die. Thus, some analog of the secondary quantization method is required with the difference that the objects (vortex loops) themselves possess an infinite number of degree of freedom with very involved dynamics. Clearly this problem can hardly be resolved in the nearest future. Some approach crucially reducing a number of degree of freedom is required.

  15. Random walking structure • The structure of any loop is determined by numerous previous reconnections. Therefore any loop consists of small parts which "remember" previous collision. These parts are uncorrelated since deterministic Kelvin wave signals do not have a time to propagate far enough. Therefore loop has a structure of random walk (like polymer chain).

  16. Gaussian model of vortex loop

  17. Statement of problem The only degree of freedom of random walk is the length l of loop. Let us introduce the distribution function n(l,t) of the density of a loop in the "space" of their lengths. It is defined as the number of loops (per unit volume) with lengths lying between l and l+dl. Knowing quantity n(l,t) and statistics of each personal loop we are able to evaluate various properties of real vortex tangle

  18. There are two main mechanisms for n(l,t) to be changed. The first one is related to deterministic motion (in fact to mutual friction shrinking or inflating loops). The second mechanism is related to random processes of recombination. We take that splitting of loop into two loop into two smaller loops occurs with the rate of self-intersection (number of events per unit time) B(l_1,l_2,l). The merging of loop occurs with the rate of collision A(l_1,l_2,l). Evolution of n(l,t)

  19. Kinetic equation

  20. Let us take vector S connecting two points of the loop. Event S=0 implies self-intersection of line with consequent reconnection and splitting of the loop. To find the rate of such events we have to find how often 3-component function S of 3 arguments vanishes. In other words we have to find number of zeroes of fluctuating function S. Evaluation of rates of self-intersection and collision

  21. Coefficients A(l_1,l_2,l) and B(l_1,l_2,l)

  22. Stationary solution to Kinetic equation (collision term=0)

  23. Vortex line density and mean curvature

  24. The Full Rate of Reconnection

  25. Evolution of Vortex Line Density

  26. Rate of VLD due to deterministic term

  27. Vinen Equation

  28. Negative flux appears when break down of loops prevails and cascade-like process of generation of smaller and smaller loops forms. There exists a number of mechanisms of disappearance of rings on very small scales. It can be e.g. acoustic radiation, collapse of lines, Kelvin waves etc. These dissipative mechanisms compensate incoming of energy into system. Thus, in this case one can observe well-developed superfluid turbulence. Low temperature case: Direct cascade

  29. The case with inverse is less clear. Inverse cascade implies the cascade-like process of generation of larger and larger loops. Unlike previous case of direct cascade, there is no apparent mechanism for disappearance of very large loops. The probable scenario is that parts of large loops are pinned on the walls. Finally a state with few lines stretching from wall to wall with poor dynamics and rare events is realized, this is a degenerated state of the vortex tangle. High temperature case: Inverse cascade

  30. conclusion • An approach considering superfluid turbulence as a network of merging and splitting of vortex loops is developed • The vortex tangle dynamics is described with use of “kinetic” equation the distribution function n(l,t) in space of lengths l of the loops. • The exact power-like solution to “kinetic” equation was obtained. That is non-equilibrium solution characterized by two mutual fluxes of length (energy) in space of loop sizes. • The result obtained were used to draw some conclusion about the structure and dynamics of the vortex tangle appeared in the superfluid turbulent HeII. (i) In particular we obtained relation between vortex line density and mean radius of curvature. (II) We also estimated the total rate of reconnections (iii) We obtained an evolution equation for vortex line density (Vinen equation) (iv) We concluded that depending on the temperature vortex tangle either forms well-developed superfluid turbulence, or degeneratesinto few lines pinned on the walls.

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