Abstract
When a system emits gravitational radiation, the Bondi mass decreases. If the Bondi energy is Hamiltonian, it can thus only be a time-dependent Hamiltonian. In this paper, we show that the Bondi energy can be understood as a time-dependent Hamiltonian on the covariant phase space. Our derivation starts from the Hamiltonian formulation in domains with boundaries that are null. We introduce the most general boundary conditions on a generic such null boundary, and compute quasi-local charges for boosts, energy and angular momentum. Initially, these domains are at finite distance, such that there is a natural IR regulator. To remove the IR regulator, we introduce a double null foliation together with an adapted Newman-Penrose null tetrad. Both null directions are surface orthogonal. We study the falloff conditions for such specific null foliations and take the limit to null infinity. At null infinity, we recover the Bondi mass and the usual covariant phase space for the two radiative modes at the full non-perturbative level. Apart from technical results, the framework gives two important physical insights. First of all, it explains the physical significance of the corner term that is added in the Wald-Zoupas framework to render the quasi-conserved charges integrable. The term to be added is simply the derivative of the Hamiltonian with respect to the background fields that drive the time-dependence of the Hamiltonian. Secondly, we propose a new interpretation of the Bondi mass as the thermodynamical free energy of gravitational edge modes at future null infinity. The Bondi mass law is then simply the statement that the free energy always decreases on its way towards thermal equilibrium.
Highlights
With δ denoting a linearised solution of the field equations
We propose a new interpretation of the Bondi mass as the thermodynamical free energy of gravitational edge modes at future null infinity
We introduce the symplectic potential in terms of a Newman-Penrose (NP) tetrad on a generic null boundary and identify the gauge symmetries and quasi-local observables on the light cone
Summary
The covariant phase space approach [8,9,10,11,12] is frequently used in relativistic field theories. Situations occur, where the action blows up at infinity and it is not immediate to infer the Hamiltonian from a 3+1 split of the action In such a situation, the covariant phase space approach provides a simple method to infer the on-shell value of the Hamiltonian, i.e. the pull-back of the Hamiltonian to the space of physical histories Hphys. The covariant phase space approach provides a simple method to infer the on-shell value of the Hamiltonian, i.e. the pull-back of the Hamiltonian to the space of physical histories Hphys This is possible, because on Hphys the Hamiltonian vector field XH coincides with the time translation ∂t, see (2.8), (2.9).
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