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The scaling laws in both cascades can be obtained from
dimensional analysis of Navier-Stokes equation as well
as in the three-dimensional case.
For the inverse energy cascade, the assumption of a constant
flux of energy
[画像:$\Pi(\ell) = - \epsilon$] toward large scales reproduces
3d-like scaling laws for velocities and characteristic times:
\begin{displaymath} u_{\ell} \sim \epsilon^{1/3} \ell^{1/3} \end{displaymath}
(1.66)
\begin{displaymath} \tau_{\ell} \sim \epsilon^{-1/3} \ell^{2/3} \end{displaymath}
(1.67)
This means that the velocity field in the inverse cascade
is rough, with scaling exponent [
画像:$h=1/3$], exactly as in the
three-dimensional case.
The prediction for the energy spectrum reads
\begin{displaymath} E(k) = C {\epsilon}^{2/3} k^{-5/3} \end{displaymath}
(1.68)
Figure 1.4:
Energy spectrum of the inverse energy cascade
[
画像:$E(k) \sim k^{-5/3}$]. In the scaling range
the energy flux (shown in the inset) is constant and negative.
The hypothesis of locality of triadic interactions in the inverse cascade
is consistent with the $k^{-3/5}$ spectrum. The transfer
is associated with the distortion of the velocity field by its own shear.
The effective shear at given wavenumber $k$ is expected to be negligibly
affected by wave-numbers $\ll k$ because the integral
[画像:$\int_0^{\infty} k^2 E(k) dk$], which measure the mean-square shear,
converges at $k = 0$. Also the contribution by high wavenumber $\gg k$
is negligible because vorticity associated with those wave-numbers
fluctuates rapidly in space and times and gives a small effective shear
across distances of order $k^{-1}$.
In absence of a large-scale sink of energy the inverse cascade
can only be quasi-steady because the peak $k_E$ of the energy spectrum
keeps moving down to ever-lower wave-numbers as
\begin{displaymath} k_E(t) \sim {\epsilon}^{-1/2} t^{-3/2} \end{displaymath}
(1.69)
while the total energy grows linearly in time
[
画像:$E(t) = \epsilon t$].
If the input of energy continues for a sufficiently long time,
the cascade can eventually reach the integral scale and energy
begins to accumulate in the lowest mode, a phenomenon which is the
analogous of Bose-Einstein condensation [
20] of a finite
two-dimensional quantum gas. This pile up of energy can
produce a large scale spectrum steeper than $k^{-3}$ which violates
the hypothesis of locality of interactions.
The presence of friction stops the energy cascade at wavenumber
\begin{displaymath} k_E \sim {\epsilon}^{-1/2} \alpha^{3/2} \end{displaymath}
(1.70)
where the energy dissipation balances the energy transfer
2ドル \alpha E_{eq} = \epsilon$.
In two-dimensional turbulence it is possible to demonstrate
the analogous of the Kolmogorov's four-fifths law.
In the limit of infinite Reynolds number the third order
(longitudinal) structure function of two-dimensional
homogeneous isotropic turbulence, evaluated for increments
$\ell $ small compared to the integral scale, and larger than the forcing
correlation length, is given in terms of the mean energy flux
per unit mass $\epsilon$ by
Together with the scaling hypothesis for the structure functions
[
画像:$S_P(\ell) \sim \ell^{\zeta_p}$] the
three-half law allows
to obtain the equivalent of $K41$ theory for the inverse
energy cascade in two-dimensional turbulence.
At variance with the three-dimensional case, where the
dimensional prediction for the scaling exponents is modified
by the presence of small scale intermittency, the statistics of velocity
fluctuations at different scale $\ell $ in the scaling range of the
inverse energy cascade are found to be roughly self-similar [21],
with small deviations from gaussianity.
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Stefano Musacchio
2004年01月09日
![画像:\includegraphics[draft=false,scale=0.7]{cascata_inversa1024.eps}](/index.cgi/larger-text/http://www.ph.unito.it/~smusacch/tesi/img245.png){kind=link}
