Bekenstein bound: Difference between revisions

In physics, the Bekenstein bound (named after Jacob Bekenstein) is an upper limit on the thermodynamic entropy S, or Shannon entropy H, that can be contained within a given finite region of space which has a finite amount of energy—or conversely, the maximum amount of information required to perfectly describe a given physical system down to the quantum level.^[1] It implies that the information of a physical system, or the information necessary to perfectly describe that system, must be finite if the region of space and the energy are finite.

The universal form of the bound was originally found by Jacob Bekenstein in 1981 as the inequality^[1][2][3] $${\displaystyle S\leq {\frac {2\pi kRE}{\hbar c}},}$$ where S is the entropy, k is the Boltzmann constant, R is the radius of a sphere that can enclose the given system, E is the total mass–energy including any rest masses, ħ is the reduced Planck constant, and c is the speed of light. Note that while gravity plays a significant role in its enforcement, the expression for the bound does not contain the gravitational constant G, and so, it ought to apply to quantum field theory in curved spacetime.

The Bekenstein–Hawking boundary entropy of three-dimensional black holes exactly saturates the bound. The Schwarzschild radius is given by $${\displaystyle r_{\rm {s}}={\frac {2GM}{c^{2}}},}$$ and so the two-dimensional area of the black hole's event horizon is $${\displaystyle A=4\pi r_{\rm {s}}^{2}={\frac {16\pi G^{2}M^{2}}{c^{4}}},}$$ and using the Planck length $${\displaystyle l_{\rm {P}}^{2}=\hbar G/c^{3},}$$ the Bekenstein–Hawking entropy is $${\displaystyle S={\frac {kA}{4\ l_{\rm {P}}^{2}}}={\frac {4\pi kGM^{2}}{\hbar c}}.}$$

One interpretation of the bound makes use of the microcanonical formula for entropy, $${\displaystyle S=k\log \Omega ,}$$ where ${\displaystyle \Omega }$ is the number of energy eigenstates accessible to the system. This is equivalent to saying that the dimension of the Hilbert space describing the system is^[4][5] $${\displaystyle \dim {\mathcal {H}}=\exp \left({\frac {2\pi RE}{\hbar c}}\right).}$$

The bound is closely associated with black hole thermodynamics, the holographic principle and the covariant entropy bound of quantum gravity, and can be derived from a conjectured strong form of the latter.^[4]

Bekenstein derived the bound from heuristic arguments involving black holes. If a system exists that violates the bound, i.e., by having too much entropy, Bekenstein argued that it would be possible to violate the second law of thermodynamics by lowering it into a black hole. In 1995, Ted Jacobson demonstrated that the Einstein field equations (i.e., general relativity) can be derived by assuming that the Bekenstein bound and the laws of thermodynamics are true.^[6][7] However, while a number of arguments were devised which show that some form of the bound must exist in order for the laws of thermodynamics and general relativity to be mutually consistent, the precise formulation of the bound was a matter of debate until Casini's work in 2008.^{[2][3] [8][9][10][11][12][13][14][15][16]}

The following is a heuristic derivation that shows ${\displaystyle S\leq K{\frac {kRE}{\hbar c}}}$ for some constant ${\displaystyle K}$. Showing that ${\displaystyle K=2\pi }$ requires a more technical analysis.

Suppose we have a black hole of mass ${\displaystyle M}$, then the Schwarzschild radius of the black hole is ${\displaystyle R_{bh}\sim {\frac {GM}{c^{2}}}}$, and the Bekenstein–Hawking entropy of the black hole is ${\displaystyle \sim {\frac {kc^{3}R_{bh}^{2}}{\hbar G}}\sim {\frac {kGM^{2}}{\hbar c}}}$.

Now take a box of energy ${\displaystyle E}$, entropy ${\displaystyle S}$, and side length ${\displaystyle R}$. If we throw the box into the black hole, the mass of the black hole goes up to ${\displaystyle M+{\frac {E}{c^{2}}}}$, and the entropy goes up by ${\displaystyle {\frac {kGME}{\hbar c^{3}}}}$. Since entropy does not decrease, ${\displaystyle {\frac {kGME}{\hbar c^{3}}}\gtrsim S}$ .

In order for the box to fit inside the black hole, ${\displaystyle R\lesssim {\frac {GM}{c^{2}}}}$ . If the two are comparable, ${\displaystyle R\sim {\frac {GM}{c^{2}}}}$, then we have derived the BH bound: ${\displaystyle S\lesssim {\frac {kRE}{\hbar c}}}$.

A proof of the Bekenstein bound in the framework of quantum field theory was given in 2008 by Casini.^[17] One of the crucial insights of the proof was to find a proper interpretation of the quantities appearing on both sides of the bound.

Naive definitions of entropy and energy density in Quantum Field Theory suffer from ultraviolet divergences. In the case of the Bekenstein bound, ultraviolet divergences can be avoided by taking differences between quantities computed in an excited state and the same quantities computed in the vacuum state. For example, given a spatial region ${\displaystyle V}$, Casini defines the entropy on the left-hand side of the Bekenstein bound as $${\displaystyle S_{V}=S(\rho _{V})-S(\rho _{V}^{0})=-\mathrm {tr} (\rho _{V}\log \rho _{V})+\mathrm {tr} (\rho _{V}^{0}\log \rho _{V}^{0})}$$ where ${\displaystyle S(\rho _{V})}$ is the Von Neumann entropy of the reduced density matrix ${\displaystyle \rho _{V}}$ associated with ${\displaystyle V}$ in the excited state ${\displaystyle \rho }$, and ${\displaystyle S(\rho _{V}^{0})}$ is the corresponding Von Neumann entropy for the vacuum state ${\displaystyle \rho ^{0}}$.

On the right-hand side of the Bekenstein bound, a difficult point is to give a rigorous interpretation of the quantity ${\displaystyle 2\pi RE}$, where ${\displaystyle R}$ is a characteristic length scale of the system and ${\displaystyle E}$ is a characteristic energy. This product has the same units as the generator of a Lorentz boost, and the natural analog of a boost in this situation is the modular Hamiltonian of the vacuum state ${\displaystyle K=-\log \rho _{V}^{0}}$. Casini defines the right-hand side of the Bekenstein bound as the difference between the expectation value of the modular Hamiltonian in the excited state and the vacuum state, $${\displaystyle K_{V}=\mathrm {tr} (K\rho _{V})-\mathrm {tr} (K\rho _{V}^{0}).}$$

With these definitions, the bound reads $${\displaystyle S_{V}\leq K_{V},}$$ which can be rearranged to give $${\displaystyle \mathrm {tr} (\rho _{V}\log \rho _{V})-\mathrm {tr} (\rho _{V}\log \rho _{V}^{0})\geq 0.}$$

This is simply the statement of positivity of quantum relative entropy, which proves the Bekenstein bound.

However, the modular Hamiltonian can only be interpreted as a weighted form of energy for conformal field theories, and when V is a sphere.

This construction allows us to make sense of the Casimir effect^[4] where the localized energy density is lower than that of the vacuum, i.e. a negative localized energy. The localized entropy of the vacuum is nonzero, and so, the Casimir effect is possible for states with a lower localized entropy than that of the vacuum. Hawking radiation can be explained by dumping localized negative energy into a black hole.

• Margolus–Levitin theorem
• Landauer's principle
• Bremermann's limit
• Kolmogorov complexity
• Beyond black holes
• Digital physics
• Limits of computation
• Chandrasekhar limit

• Jacob D. Bekenstein, "Bekenstein-Hawking entropy", Scholarpedia, Vol. 3, No. 10 (2008), p. 7375, doi:10.4249/scholarpedia.7375.
• Jacob D. Bekenstein's website at the Racah Institute of Physics, Hebrew University of Jerusalem, which contains a number of articles on the Bekenstein bound.
• O'Dowd, Matt (September 12, 2018). "How Much Information is in the Universe?". PBS Space Time. Archived from the original on 2021-12-12 – via YouTube.