Spin-2 Amplitudes in Black-Hole Evaporation
Abstract
Quantum amplitudes for s=2 gravitational-wave perturbations of Einstein/scalar collapse to a black hole are treated by analogy with s=1 Maxwell perturbations. The spin-2 perturbations split into parts with odd and even parity. We use the Regge-Wheeler gauge; at a certain point we make a gauge transformation to an asymptotically-flat gauge, such that the metric perturbations have the expected falloff behaviour at large radii. By analogy with s=1, for s=2 natural 'coordinate' variables are given by the magnetic part Hij (i,j=1,2,3) of the Weyl tensor, which can be taken as boundary data on a final space-like hypersurface F. For simplicity, we take the data on the initial surface I to be exactly spherically-symmetric. The (large) Lorentzian proper-time interval between I and F, measured at spatial infinity, is denoted by T. We follow Feynman's +iε prescription and rotate T into the complex: TT (-iθ), for 0<θ≤π/2. The corresponding complexified classical boundary-value problem is expected to be well-posed. The Lorentzian quantum amplitude is recovered by taking the limit as θ 0+. For boundary data well below the Planck scale, and for a locally supersymmetric theory, this involves only the semi-classical amplitude (iS(2) class, where S(2) class denotes the second-variation classical action. The relations between the s=1 and s=2 natural boundary data, involving supersymmetry, are investigated using 2-component spinor language in terms of the Maxwell field strength φAB=φ(AB) and the Weyl spinor ABCD=(ABCD).
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