Hawking energy

The Hawking energy or Hawking mass is one of the possible definitions of mass in general relativity. It is a measure of the bending of ingoing and outgoing rays of light that are orthogonal to a 2-sphere surrounding the region of space whose mass is to be defined. The Hawking energy or Hawking mass is one of the possible definitions of mass in general relativity. It is a measure of the bending of ingoing and outgoing rays of light that are orthogonal to a 2-sphere surrounding the region of space whose mass is to be defined. Let ( M 3 , g a b ) {displaystyle ({mathcal {M}}^{3},g_{ab})} be a 3-dimensional sub-manifold of a relativistic spacetime, and let Σ ⊂ M 3 {displaystyle Sigma subset {mathcal {M}}^{3}} be a closed 2-surface. Then the Hawking mass m H ( Σ ) {displaystyle m_{H}(Sigma )} of Σ {displaystyle Sigma } is defined to be where H {displaystyle H} is the mean curvature of Σ {displaystyle Sigma } . In the Schwarzschild metric, the Hawking mass of any sphere S r {displaystyle S_{r}} about the central mass is equal to the value m {displaystyle m} of the central mass. A result of Geroch implies that Hawking mass satisfies an important monotonicity condition. Namely, if M 3 {displaystyle {mathcal {M}}^{3}} has nonnegative scalar curvature, then the Hawking mass of Σ {displaystyle Sigma } is non-decreasing as the surface Σ {displaystyle Sigma } flows outward at a speed equal to the inverse of the mean curvature. In particular, if Σ t {displaystyle Sigma _{t}} is a family of connected surfaces evolving according to where H {displaystyle H} is the mean curvature of Σ t {displaystyle Sigma _{t}} and ν {displaystyle u } is the unit vector opposite of the mean curvature direction, then Said otherwise, Hawking mass is increasing for the inverse mean curvature flow. Hawking mass is not necessarily positive. However, it is asymptotic to the ADM or the Bondi mass, depending on whether the surface is asymptotic to spatial infinity or null infinity.