Fully nonlinear gravitational instabilities for expanding spherical symmetric Newtonian universes with inhomogeneous density and pressure

Abstract

Nobel Prize laureate P.J.E. Peebles [24] has emphasized the importance and difficulties of studying the large scale clustering of matter in cosmology. Nonlinear gravitational instability plays a central role in understanding the clustering of matter and the formation of nonlinear structures in the universe and stellar systems. However, there is no rigorous result on the nonlinear analysis of this instability except for some particular exact solutions without pressure, and numerical and phenomenological approaches. Both Rendall [26] and Mukhanov [21] have highlighted the challenge posed by nonlinear gravitational instability with effective pressure. This has been a longstanding open problem in astrophysics for over a century since the occurrence of linearized Jeans instabilities in Newtonian universes in 1902. This article contributes to a fully nonlinear analysis of the gravitational instability for the Euler-Possion system which models expanding Newtonian universes with inhomogeneous density and pressure. The exponential or finite-time increasing blowups of the density contrast $\varrho$ can be determined, which may account for the considerably faster growth rate of nonlinear structures observed in astrophysics than that suggested by the classical Jeans instability. We believe this is the first rigorous result for the nonlinear Jeans instability with effective pressure and the method is concise and robust.