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.

Definition

Let $(\mathcal{M}^3, g_{ab})$ be a 3-dimensional sub-manifold of a relativistic spacetime, and let $\Sigma \subset \mathcal{M}^3$ be a closed 2-surface. Then the Hawking mass $m_H(\Sigma)$ of $\Sigma$ is defined^[1] to be

m_H(\Sigma) := \sqrt{\frac{\text{Area}\,\Sigma}{16\pi}}\left( 1 - \frac{1}{16\pi}\int_\Sigma H^2 da \right),

where $H$ is the mean curvature of $\Sigma$ .

Properties

In the Schwarzschild metric, the Hawking mass of any sphere $S_r$ about the central mass is equal to the value $m$ of the central mass.

A result of Geroch^[2] implies that Hawking mass satisfies an important monotonicity condition. Namely, if $\mathcal{M}^3$ has nonnegative scalar curvature, then the Hawking mass of $\Sigma$ is non-decreasing as the surface $\Sigma$ flows outward at a speed equal to the inverse of the mean curvature. In particular, if $\Sigma_t$ is a family of connected surfaces evolving according to

\frac{dx}{dt} = \frac{1}{H}\nu(x),

where $H$ is the mean curvature of $\Sigma_t$ and $\nu$ is the unit vector opposite of the mean curvature direction, then

\frac{d}{dt}m_H(\Sigma_t) \geq 0.

Said otherwise, Hawking mass is increasing for the inverse mean curvature flow.^[3]

Hawking mass is not necessarily positive. However, it is asymptotic to the ADM^[4] or the Bondi mass, depending on whether the surface is asymptotic to spatial infinity or null infinity.^[5]

References

↑ Page 21 of Schoen, Richard, 2005, "Mean Curvature in Riemannian Geometry and General Relativity," in Global Theory of Minimal Surfaces: Proceedings of the Clay Mathematics Institute 2001 Summer School, David Hoffman (Ed.), p.113-136.
↑ Geroch, Robert. 1973. "Energy Extraction." doi:10.1111/j.1749-6632.1973.tb41445.x.
↑ Lemma 9.6 of Schoen (2005).
↑ Section 4 of Yuguang Shi, Guofang Wang and Jie Wu (2008), "On the behavior of quasi-local mass at the infinity along nearly round surfaces".
↑ Section 2 of Shing Tung Yau (2002), "Some progress in classical general relativity," Geometry and Nonlinear Partial Differential Equations, Volume 29.

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[1] Page 21 of Schoen, Richard, 2005, "Mean Curvature in Riemannian Geometry and General Relativity," in Global Theory of Minimal Surfaces: Proceedings of the Clay Mathematics Institute 2001 Summer School, David Hoffman (Ed.), p.113-136.

[2] Geroch, Robert. 1973. "Energy Extraction." doi:10.1111/j.1749-6632.1973.tb41445.x.

[3] Lemma 9.6 of Schoen (2005).

[4] Section 4 of Yuguang Shi, Guofang Wang and Jie Wu (2008), "On the behavior of quasi-local mass at the infinity along nearly round surfaces".

[5] Section 2 of Shing Tung Yau (2002), "Some progress in classical general relativity," Geometry and Nonlinear Partial Differential Equations, Volume 29.

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Hawking energy

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Definition

Properties

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