Self-similar solution in the Leith model of turbulence: anomalous power law and asymptotic analysis

Abstract: We consider a Leith model of turbulence (Leith C 1967 Phys. Fluids 10 1409) in which the energy spectrum obeys a nonlinear diffusion equation. We analytically prove the existence of a self-similar solution with a power-law asymptotic on the low-wavenumber end and a sharp boundary on the high-wavenumber end, which propagates to infinite wavenumbers in a finite-time t*. We prove that this solution has a power-law asymptotic with an anomalous exponent x*, which is less than the Kolmogorov value, x* > 5/3. This is… Show more

“…Similar behaviour was observed for the differential (Leith) and integrodifferential (EDQNM) closures of Navier-Stokes turbulence in [9] and [10] respectively. Rigorous bounds for the anomalous index in the Leith model were recently found in [11]: the index was proven to be strictly greater that Kolmogorov's 5/3 and strictly less than 1.95 which agrees with the numerical value ≈ 1.85.…”

“…A local Hopf bifurcation of creation of a limiting cycle around P 3 occurs at x = x c . As found in [9] and [11], the vicinity of the point P 1 corresponds to the η → 0 part of the solution whereas point P 2 corresponds to the sharp front, η = 1. The goal is to find such x = x that one could have an orbit connecting P 1 and P 2 , i.e.…”

“…Note that the asymptotic behaviors (a) and (c) observed in the numerics can be proven mathematically using the bounding theorem of [11]. It suffices to recall that x − < x K < x < x + , explicitly compute x + − x − , and observe that this difference vanishes in both asymptotics.…”

“…Like in [9] and [11], we will first find an autonomous system equivalent to equation (6). In addition to being autonomous, the new system must have non-singular fixed points.…”

“…In section 2, we describe a generalized version of Leith Model that can be used as a toy model for turbulent systems with a finite-capacity spectrum. In section 3, the calculations of [9] and [11] are extended to infer the existence of self-similar solutions whose energy spectra are steeper than Kolmogorov's. In section 4, we use numerics to characterize this anomaly, and construct a phenomenological fitting formula for the anomalous exponent as a function of the parameters of the model.…”

Anomalous spectral laws in differential models of turbulence

“…Similar behaviour was observed for the differential (Leith) and integrodifferential (EDQNM) closures of Navier-Stokes turbulence in [9] and [10] respectively. Rigorous bounds for the anomalous index in the Leith model were recently found in [11]: the index was proven to be strictly greater that Kolmogorov's 5/3 and strictly less than 1.95 which agrees with the numerical value ≈ 1.85.…”

“…A local Hopf bifurcation of creation of a limiting cycle around P 3 occurs at x = x c . As found in [9] and [11], the vicinity of the point P 1 corresponds to the η → 0 part of the solution whereas point P 2 corresponds to the sharp front, η = 1. The goal is to find such x = x that one could have an orbit connecting P 1 and P 2 , i.e.…”

“…Note that the asymptotic behaviors (a) and (c) observed in the numerics can be proven mathematically using the bounding theorem of [11]. It suffices to recall that x − < x K < x < x + , explicitly compute x + − x − , and observe that this difference vanishes in both asymptotics.…”

“…Like in [9] and [11], we will first find an autonomous system equivalent to equation (6). In addition to being autonomous, the new system must have non-singular fixed points.…”

“…In section 2, we describe a generalized version of Leith Model that can be used as a toy model for turbulent systems with a finite-capacity spectrum. In section 3, the calculations of [9] and [11] are extended to infer the existence of self-similar solutions whose energy spectra are steeper than Kolmogorov's. In section 4, we use numerics to characterize this anomaly, and construct a phenomenological fitting formula for the anomalous exponent as a function of the parameters of the model.…”

Anomalous spectral laws in differential models of turbulence

Complementary remarks to properties of the energy spectrum in Leith's model of turbulence

Invariant submodels and exact solutions of the generalization of the Leith model of the wave turbulence