Holeum

Holeums are hypothetical stable, quantized gravitational bound states of primordial or micro black holes. Holeums were proposed by L.K. Chavda and Abhijit Chavda in 2002.^[1] They have all the properties associated with cold dark matter. Holeums are not black holes, even though they are made up of black holes.

Properties

The binding energy $E_{n}$ of a holeum that consists of two identical micro black holes of mass $m$ is given by^[2]

E_{n}=-\frac{mc^{2}\alpha_{g}^{2}}{4n^{2}}

in which $n$ is the principal quantum number, $n=1,2,...,\infty$ and $\alpha_{g}$ is the gravitational counterpart of the fine structure constant. The latter is given by

\alpha_{g}=\frac{m^{2}G}{\hbar c}=\frac{m^{2}}{m_{P}^{2}}

where:

\hbar

is the Planck constant divided by

2\pi

;

c

is the speed of light in vacuum;

G

is the gravitational constant.

The nth excited state of a holeum then has a mass that is given by

m_{H}=2m+\frac{E_{n}}{c^{2}}

The holeum's atomic transitions cause it to emit gravitational radiation.

The radius of the nth excited state of a holeum is given by

r_{n}=\left( \frac{n^{2}R}{\alpha_{g}^{2}}\right) \left( \frac{\pi^{2}}{{8}}\right)

where:

R=\left( \frac{2mG}{c^{2}}\right)

is the Schwarzschild radius of the two identical micro black holes that constitute the holeum.

The holeum is a stable particle. It is the gravitational analogue of the hydrogen atom. It occupies space. Although it is made up of black holes, it itself is not a black hole. As the holeum is a purely gravitational system, it emits only gravitational radiation and no electromagnetic radiation. The holeum can therefore be considered to be a dark matter particle.^[3]

Macro holeums and their properties

A macro holeum is a quantized gravitational bound state of a large number of micro black holes. The energy eigenvalues of a macro holeum consisting of $k$ identical micro black holes of mass $m$ are given by^[4]

E_{k}=-\frac{p^{2}mc^{2}}{2n_{k}^{2}}\left( 1-\frac{p^{2}}{6n^{2}}\right)^{2}

where $p=k\alpha_{g}$ and $k\gg2$ . The system is simplified by assuming that all the micro black holes in the core are in the same quantum state described by $n$ , and that the outermost, $k^{th}$ micro black hole is in an arbitrary quantum state described by the principal quantum number $n_{k}$ .

The physical radius of the bound state is given by

r_{k}=\frac{\pi^{2}kRn_{k}^{2}}{16p^{2}\left( 1-\frac{p^{2}}{6n^{2}}\right)}

The mass of the macro holeum is given by

M_{k}=mk\left( 1-\frac{p^{2}}{6n^{2}}\right)

The Schwarzschild radius of the macro holeum is given by

R_{k}=kR\left( 1-\frac{p^{2}}{6n^{2}}\right)

The entropy of the system is given by

S_{k}=k^{2}S\left( 1-\frac{p^{2}}{6n^{2}}\right)

where $S$ is the entropy of the individual micro black holes that constitute the macro holeum.

The ground state of macro holeums

The ground state of macro holeums is characterized by $n=\infty$ and $n_{k}=1$ . The holeum has maximum binding energy, minimum physical radius, maximum Schwarzschild radius, maximum mass, and maximum entropy in this state.

Such a system can be thought of as consisting of a gas of $k-1$ free ( $n=\infty$ ) micro black holes that is bounded and therefore isolated from the outside world by a solitary outermost micro black hole whose principal quantum number is $n_{k}=1$ .

Stability

It can be seen from the above equations that the condition for the stability of holeums is given by

\frac{p^{2}}{6n^{2}}<1

Substituting the relations $p=k\alpha _{g}$ and $\alpha _{g}=\frac{m^{2}}{m_{P}^{2}}$ into this inequality, the condition for the stability of holeums can be expressed as

m<m_{P}\left( 6\right) ^{\frac{1}{4}}\left( \frac{n}{k}\right) ^{\frac{1}{2}}

The ground state of holeums is characterized by $n=\infty$ , which gives us $m<\infty$ as the condition for stability. Thus, the ground state of holeums is guaranteed to be always stable.

Black holeums

A holeum is a black hole if its physical radius is less than or equal to its Schwarzschild radius, i.e. if

r_{k}\leqslant R_{k}

Such holeums are termed black holeums. Substituting the expressions for $r_{k}$ and $R_{k}$ , and simplifying, we obtain the condition for a holeum to be a black holeum to be

m\geqslant \frac{m_{P}}{2}\left( \frac{\pi n_{k}}{k}\right) ^{\frac{1}{2}}

For the ground state, which is characterized by $n_{k}=1$ , this reduces to

m\geqslant \frac{m_{P}}{2}\left( \frac{\pi}{k}\right) ^{\frac{1}{2}}

Black holeums are an example of black holes with internal structure. Black holeums are quantum black holes whose internal structure can be fully predicted by means of the quantities $k$ , $m$ , $n$ , and $n_{k}$ .

Holeums and cosmology

Holeums are speculated to be the progenitors of a class of short duration gamma ray bursts.^[5]^[6] It is also speculated that holeums give rise to cosmic rays of all energies, including ultra-high-energy cosmic rays.^[7]

References

↑ L.K. Chavda & Abhijit Chavda, Dark matter and stable bound states of primordial black holes
↑ L.K. Chavda & Abhijit Chavda, Dark matter and stable bound states of primordial black holes
↑ M. Yu. Khlopov, Primordial Black Holes
↑ L.K. Chavda & Abhijit Chavda, Quantized Gravitational Radiation from Black Holes and other macro holeums in the Low Frequency Domain
↑ S. Al Dallal, Holeums as potential candidates for some short-lived gamma ray bursts
↑ S. Al Dallal, Primordial black holes and holeums as progenitors of galactic diffuse gamma-ray background
↑ L.K. Chavda & Abhijit Chavda, Ultra High Energy Cosmic Rays from decays of holeums in Galactic Halos

External links

[1] L.K. Chavda & Abhijit Chavda, Dark matter and stable bound states of primordial black holes

[2] L.K. Chavda & Abhijit Chavda, Dark matter and stable bound states of primordial black holes

[3] M. Yu. Khlopov, Primordial Black Holes

[4] L.K. Chavda & Abhijit Chavda, Quantized Gravitational Radiation from Black Holes and other macro holeums in the Low Frequency Domain

[5] S. Al Dallal, Holeums as potential candidates for some short-lived gamma ray bursts

[6] S. Al Dallal, Primordial black holes and holeums as progenitors of galactic diffuse gamma-ray background

[7] L.K. Chavda & Abhijit Chavda, Ultra High Energy Cosmic Rays from decays of holeums in Galactic Halos

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[2]

[3]

[4]

[5]

[6]

[7]

Holeum

Contents

Properties

Macro holeums and their properties

The ground state of macro holeums

Stability

Black holeums

Holeums and cosmology

See also

References

External links

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