We present an experimental test of Corrsin's conjecture against experimental data obtained by a particle tracking technique in approximately homogeneous and isotropic turbulent flow at Reynolds numbers R lambda approximate to 100. The conjecture states that
R-L(t) approximate to integral R-E(x, t)G(x, t) d(3) x,
where R-L(t-t ') = < v(t)center dot v(t ')> is the Lagrangian velocity covariance function, G is the single particle mean Green's function, and R-E(x-x ', t-t ') &3bond; < u( x, t) center dot u (x ' , t ')> is the Eulerian two-point, two-time velocity covariance function. All terms in the relation have been measured in the experiment. The equation is exact if a conditional Lagrangian velocity function R-L(t vertical bar x) is inserted in place of R-E(x, t) on the right-hand side. R-L(t vertical bar x) is obtained by restricting sampling of the two velocities to situations where both belong to the same fluid particle trajectory. The experimental data show that the R-E(x, t) and R-L(t vertical bar x) behave fundamentally differently, thereby seriously questioning the rationale of the conjecture. The estimate of R-L(t), based on Corrsin's conjecture and the experimentally determined R-E and G, is found to decrease too fast compared to the directly measured R-L, thus underestimating the Lagrangian timescale by about 40%. Even asymptotically (t -> infinity) the estimate is considerably lower than the measured Lagrangian correlation function. The simpler relation R-L(t) = R-E( 0, t), which has also been attributed to Corrsin, appears to agree much better with data. Various simple physical models of the spatiotemporal Eulerian correlation function have been compared with data, and models inspired by eddy sweeping seem to perform well.

• 出版日期2005-6-14