On the formation of shock for quasilinear wave equations by pulse with weak intensity

Abstract

In this paper we continue to study the shock formation for the 3-dimensional quasilinear wave equation alignmain eq -(1+3G"(0)(∂tφ)2)∂2tφ+φ=0, align with G"(0) being a non-zero constant. Since main eq admits global-in-time solution with small initial data, to present shock formation, we consider a class of large data. Moreover, no symmetric assumption is imposed on the data. Compared to our previous work [18], here we pose data on the hypersurface \(t,x)|t=-r0\ instead of \(t,x)|t=-2\, with r0 being arbitrarily large. We prove an a priori energy estimate independent of r0. Therefore a complete description of the solution behavior as r0→∞ is obtained. This allows us to relax the restriction on the profile of initial data which still guarantees shock formation. Since main eq can be viewed as a model equation for describing the propagation of electromagnetic waves in nonlinear dielectric, the result in this paper reveals the possibility to use wave pulse with weak intensity to form electromagnetic shocks in laboratory. A main new feature in the proof is that all estimates in the present paper do not depend on the parameter r0, which requires different methods to obtain energy estimates. As a byproduct, we prove the existence of semi-global-in-time solutions which lead to shock formation by showing that the limits of the initial energies exist as r0→∞. The proof combines the ideas in [5] where the the formation of shocks for 3-dimensional relativistic compressible Euler equations with small initial data is established, and the short pulse method introduced in [6] and generalized in [15], where the formation of black holes in general relativity is proved.