This paper proposes temporal scaling laws of the density-weighted energy spectrum for compressible turbulence in terms of dissipation rate, frequency and the Mach number. The study adopts the incomplete similarity theory in the scaling analysis of compressible turbulence motion. The investigation shows that the temporal Eulerian and Lagrangian energy spectra approach the −53−53 and −2−2 power laws when the Mach number M tends to reach unity and infinity, respectively
An exact relation has been derived for homogeneous polytropic turbulence in terms of the two-point f...
In this paper we develop spectral laws for the small- and large-wavenumber regimes of the energy and...
The scaling laws of the temperature structure functions and their relation with those of velocity ha...
We find an asymptotic expression for the characteristic timescales of decorrelation processes in wea...
To describe the small-scale intermittency of turbulence, a self-similarity is imposed on the probabi...
Scaling arguments are applied directly to the Navier-Stokes equations with the isentropic-flow stipu...
A new energy cascade principle, synchro-cascade pattern, to better understand the mechanism of turbu...
To overcome the difficulty in the DNS of compressible turbulence at high turbulent Mach number, a ne...
An extensive investigation of velocity fluctuation spectra has been performed in the weakly compress...
We investigate how compressibility affects the turbulent statistics from a Lagrangian point of view,...
The physical nature of compressible turbulence is of fundamental importance in a variety of astrophy...
Multi-fractal scaling in the transition to the dissipative regime for fully-developed compressible ...
The two-point correlation function of the energy dissipation, obtained from a one-point time record ...
In statistically stationary conditions, the turbulent energy spectrum in a high Reynolds number flow...
Compressible turbulence shapes the structure of the interstellar medium of our Galaxy and likely pla...
An exact relation has been derived for homogeneous polytropic turbulence in terms of the two-point f...
In this paper we develop spectral laws for the small- and large-wavenumber regimes of the energy and...
The scaling laws of the temperature structure functions and their relation with those of velocity ha...
We find an asymptotic expression for the characteristic timescales of decorrelation processes in wea...
To describe the small-scale intermittency of turbulence, a self-similarity is imposed on the probabi...
Scaling arguments are applied directly to the Navier-Stokes equations with the isentropic-flow stipu...
A new energy cascade principle, synchro-cascade pattern, to better understand the mechanism of turbu...
To overcome the difficulty in the DNS of compressible turbulence at high turbulent Mach number, a ne...
An extensive investigation of velocity fluctuation spectra has been performed in the weakly compress...
We investigate how compressibility affects the turbulent statistics from a Lagrangian point of view,...
The physical nature of compressible turbulence is of fundamental importance in a variety of astrophy...
Multi-fractal scaling in the transition to the dissipative regime for fully-developed compressible ...
The two-point correlation function of the energy dissipation, obtained from a one-point time record ...
In statistically stationary conditions, the turbulent energy spectrum in a high Reynolds number flow...
Compressible turbulence shapes the structure of the interstellar medium of our Galaxy and likely pla...
An exact relation has been derived for homogeneous polytropic turbulence in terms of the two-point f...
In this paper we develop spectral laws for the small- and large-wavenumber regimes of the energy and...
The scaling laws of the temperature structure functions and their relation with those of velocity ha...