Holographic renormalization of asymptotically flat spacetimes

Abstract

A new local, covariant ‘counter-term’ is used to construct a variational principle for asymptotically flat spacetimes in any spacetime dimension d ⩾ 4. The new counter-term makes direct contact with more familiar background subtraction procedures, but is a local algebraic function of the boundary metric and Ricci curvature. The corresponding action satisfies two important properties required for a proper treatment of semi-classical issues and, in particular, to connect with any dual non-gravitational description of asymptotically flat space. These properties are that (1) the action is finite on-shell and (2) asymptotically flat solutions are stationary points under all variations preserving asymptotic flatness, i.e., not just under variations of compact support. Our definition of asymptotic flatness is sufficiently general to allow the magnetic part of the Weyl tensor to be of the same order as the electric part and thus, for d = 4, to have non-vanishing NUT charge. Definitive results are demonstrated when the boundary is either a cylindrical or a hyperbolic (i.e., de Sitter space) representation of spacelike infinity (i0), and partial results are provided for more general representations of i0. For the cylindrical or hyperbolic representations of i0, similar results are also shown to hold for both a counter-term proportional to the square-root of the boundary Ricci scalar and for a more complicated counter-term suggested previously by Kraus, Larsen and Siebelink. Finally, we show that such actions lead, via a straightforward computation, to conserved quantities at spacelike infinity which agree with, but are more general than, the usual (e.g., ADM) results.