On the Buchdahl inequality for spherically symmetric static shells
Abstract
A classical result by Buchdahl Bu1 shows that for static solutions of the spherically symmetric Einstein-matter system, the total ADM mass M and the area radius R of the boundary of the body, obey the inequality 2M/R≤ 8/9. The proof of this inequality rests on the hypotheses that the energy density is non-increasing outwards and that the pressure is isotropic. In this work neither of Buchdahl's hypotheses are assumed. We consider non-isotropic spherically symmetric shells, supported in [R0,R1], R0>0, of matter models for which the energy density ≥ 0, and the radial- and tangential pressures p≥ 0 and q, satisfy p+q≤, ≥ 1. We show a Buchdahl type inequality for shells which are thin; given an ε<1/4 there is a >0 such that 2M/R1≤ 1- when R1/R0≤ 1+ε. It is also shown that for a sequence of solutions such that R1/R0 1, the limit supremum of 2M/R1 of the sequence is bounded by ((2+1)2-1)/(2+1)2. In particular if =1, which is the case for Vlasov matter, the boumd is 8/9. The latter result is motivated by numerical simulations AR2 which indicate that for non-isotropic shells of Vlasov matter 2M/R1≤ 8/9, and moreover, that the value 8/9 is approached for shells with R1/R0 1. In An2 a sequence of shells of Vlasov matter is constructed with the properties that R1/R0 1, and that 2M/R1 equals 8/9 in the limit. We emphasize that in the present paper no field equations for the matter are used, whereas in An2 the Vlasov equation is important.
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