Asymptotic self-similar solutions with a characteristic time-scale

Abstract

For a wide variety of initial and boundary conditions, adiabatic one dimensional flows of an ideal gas approach self-similar behavior when the characteristic length scale over which the flow takes place, R, diverges or tends to zero. It is commonly assumed that self-similarity is approached since in the R∞(0) limit the flow becomes independent of any characteristic length or time scales. In this case the flow fields f(r,t) must be of the form f(r,t)=tαfF(r/R) with R( t)α. We show that requiring the asymptotic flow to be independent only of characteristic length scales imply a more general form of self-similar solutions, f(r,t)=RδfF(r/R) with R Rδ, which includes the exponential (δ=1) solutions, R et/τ. We demonstrate that the latter, less restrictive, requirement is the physically relevant one by showing that the asymptotic behavior of accelerating blast-waves, driven by the release of energy at the center of a cold gas sphere of initial density r-ω, changes its character at large ω: The flow is described by 0δ<1, R t1/(1-δ), solutions for ω<ωc, by δ>1 solutions with R (-t)1/(δ-1) diverging at finite time (t=0) for ω>ωc, and by exponential solutions for ω=ωc (ωc depends on the adiabatic index of the gas, ωc8 for 4/3<γ<5/3). The properties of the new solutions obtained here for ωωc are analyzed, and self-similar solutions describing the t>0 behavior for ω>ωc are also derived.