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Moscow 2013

16th Lomonosov Conference

Particle Accretion onto Miniholes
Michael L. Fil'chenkov Yuri P. Laptev
Institute of Gravitation and Cosmology, Peoples' Friendship University of Russia, Moscow
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Outline
· Introduction · Classical Accretion onto Black Holes · Quantum Hydrodynamics · Quantum Accretion on Miniholes · Conclusion

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Introduction
A quantum accretion of baryons onto miniholes has been considered in the framework of E. Madelung's quantum hydrodynamics. The total luminosity of the accretion disc and the energy of quanta being emitted have been calculated. The results obtained may be of importance for interpreting the electromagnetic radiation of graviatoms comprising particles captured by miniholes.

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Classical Accretion onto Black Holes
A classical model of disc accretion onto black holes at the final stage of close binary evolution may serve as the starting point. Due to a differential rotation of the disc there arise shear stresses between adjacent layers resulting in angular momentum transfer outward. The matter in the interior approaches the disc centre. The gas is being heated up to elevated temperatures because of friction emitting thermal radiation.
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The total luminosity of the accretion disc

Ld = GMm , 2Ri
the last stable orbit radius. Since

(1 )

where M is the black hole mass, m is the accretion rate, Ri is

R = 6GM , i c2 we obtain

(2 )

Ld = 1 mc2 . 12

(3 )
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Quantum Hydrodynamics
Calculation of a quantum accretion of baryons onto the miniholes may be considered in the framework of E. Madelung's quantum hydrodynamics. The wave function is written in the form
iS

= e ,
where is the probability density, S is the action. From SchrЖdinger's equation
2 i = - +U t 2m

(4 )

(5)
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follows the equations of quantum hydrodynamics:

+ 1 S = 0 , t m S + 1 S 2 +U - 2 = 0 , t 2m 2m

(6) (7)

where the last term

Q =-

2m

2

(8 )

is Bohm's potential, m is the particle mass. From (7) we have

S =-E, S = 2m E -U - Q . t

(9)
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Quantum Accretion on Miniholes
The stationary quantum accretion rate defined in terms of a substantial derivative reads

m = S dV ,
which reduces to

(1 0 )

m = 4

n=2

3rg

dSn d n r 2dr , dr dr

(11)

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where

dSn = 2m[E -U (r) - Q ] , n n dr U (r ) =- GMm , r rg = 2GM , c2 En = Qn ,

(12) (1 3 ) (1 4 ) (1 5 ) (1 6 )
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n =

exp 2

gr2 , naB

- 2rg naB

Moscow 2013

16th Lomonosov Conference

providing

r
where
g aB

g naB , r

g l 2aB ,

(1 7 )

=

2

GMm2

.

(1 8 )

Thus we consider asymptotic values of the baryon location probabilities on higher hydrogen-like levels.

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The quantum accretion intensity
24 2 I = g A( g ) m c , 3

(19)

where

A( g )

=

n=2

1 1- 12 , gn n3/ 2 c

(20) (2 1 )

g = GMm

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( x) = 2 e-t2 dt .

x

(2 2 )

0

The thermal radiation energy

= 0.8424 A ( g )mc2 .
So, we have

1 4

(23)

I = 5.751019 erg s
for g = 1 , m = m p . 2

-1 and

= 515 MeV

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Conclusion
The baryons do not satisfy the geometrical condition of graviatom existence, since their sizes exceed the gravitational radii of miniholes. There occurs a quantum accretion of baryons onto mini-holes which we have considered in the framework of E. Madelung's quantum hydrodynamics. The energies and intensities of the thermal radiation being due to the accretion of baryons onto mini-holes exceed the corresponding values for the dipole radiation of the graviatoms providing the baryons' sizes to be neglected.
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