PHYSICS

POSSIBILITIES OF DARK MATTER ELEMENTARY

PARTICLES REGISTRATION

V.S. Gorelik

P.N. Lebedev Physical Institute of the Russian Academy of Sciences,

Moscow, Russian Federation

e-mail:

gorelik@sci.lebedev.ru

The paper considers the modern opportunities for experimental detection of dark

matter particles (axions). In accordance with the theoretical predictions, these

particles have very small rest mass corresponding to the energy in the range of

0.001. . . 1.0 meV. It discusses the possibilities of the visible range laser radiation

conversion into the emission of axions both in vacuum and in material media as

well as the inverse processes using experimental facilities for the Primakoff effect

observation (“Light shining through wall”). It is proposed to implement a stimulated

photon-axion conversion for pumping while using the pulsed laser sources with

a high spectral intensity of radiation. To improve the efficiency of the photon-

axion conversion, it is also suggested to use the dielectric media characterized

by the presence of unitary polaritons in their spectrum, if their refractive index is

close to one. In this case, the synchronism conditions can be fulfilled during an

elementary process of axion-photon conversion. Schemes of the possible experiments

are presented to observe the processes of conversion of axions into microwave photons

at low temperatures in a strong magnetic field.

Keywords

:

axion, parafoton, resonator, receiver, rest mass, conversion, laser,

generation.

According to the modern concepts of high-energy physics [1-4] about

scenarios for the evolution of the Universe, after the initial homogenious

and isotropic state of the physical vacuum, an irreversible phase transition

occurred that resulted in reduction of the vacuum symmetry. The so-called

standard model of this phase transition is based on the use of local (gauge)

symmetry specified by the group

SU

2

×

U(1)

. The conclusion of this

theory is the prediction of the scalar field formation in vacuum, specifying

the symmetry of low temperature phase and leading to the formation of

massive elementary particles. In particular, in the spectrum of elementary

particles in a high-energy field, the existence of a “heavy” scalar particle —

the Higgs boson [4–7], has been predicted, which is being intensively

searched for in recent years using experimental facilities, which generate

elementary particles with the energy above 1 TeV. This particle is supposed

to be detected as a result of the analysis of the allowed processes of scalar

Higgs boson decay into pairs of gamma-quanta, the presence of which

may be determined by traditional methods known in elementary-particle

physics. Along with a scalar Higgs boson, also called amplitudon, in the

theory of phase transition in vacuum there is a massless Nambu – Goldstone

boson called phason.

ISSN 1812-3368. Herald of the BMSTU. Series “Natural Sciences”. 2014. No. 6

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