On the possibility of detection of charged massive particles of dark matter from the board of artificial satellites by acoustic method

1Golubnichii, PI, 1Kudlenko, VO, 1Reshetnyak, DV
1Volodymyr Dahl East Ukrainian National University, Lugansk, Ukraine
Kosm. nauka tehnol. 2003, 9 ;(Supplement1):068-071
Publication Language: Russian
Using equations of radiation acoustics within the framework of the thermal mechanism of radiation of elastic waves, we analyzed the possibility of the detection of charged massive particles of dark matter by acoustic method from the board of satellites.
1. Belova M. V., Gollmina I. P., and Rastorguev D. L. Piezoelectric Polimeric Strain Detectors. Prib. Tekh. Eksp., No. 6, 160—163 (1988) [in Russian].
2. Gorbunov D. S., Dubovskii S. L., Troitskii S. V. Gauge mechanism of mediation of supersymmetry breaking. Uspekhi Fizicheskikh Nauk, 169 (7), 705—736 (1999) [in Russian].
3. Dolgov A. D., Zel'dovich Ya. B., Sazhin M. V. Cosmology of the early universe, 199 p. (Izd-vo MGU, Moscow, 1988) [in Russian].
4. Kotel'nikov K. A., Lyamshev L. M., Merzon G. I., et al. Search for charged massive particles of dark matter using satellite-based acoustic detectors. Akusticheskij zhurn., 44 (1), 76—83 (1998) [in Russian].
5. Lifshits I. M., Kaganov M. I., Tanatarov L. V. On the theory of radiation-induced changes in metals. Atomnaya Energiya, 6 (4), 391—402 (1959) [in Russian].
6. Lyamshev L. M. Laser Thermooptical Excitation of Sound, 237 p. (Nauka, Moscow, 1989) [in Russian].
7. Rubakov V. A. Elementary particle physics and cosmology: current status and prospects. Uspekhi Fizicheskikh Nauk, 169 (12), 1299—1310 (1999) [in Russian].
8. Grigoriev I. S., Meilikhov E. Z. (Eds.) Handbook of Physical Quantities, 1232 p. (Jenergoagomizdat, Moscow, 1991) [in Russian].
9. Bernabei R., et al. In: Phys. Lett., B450, 448 (1999).
10. de Rujula A., Glashow S. L., Uri Sarid. Charged dark matter. CERN-T11-5490/89: Preprint CERN, 1—24 (1989).

11. Ellis J. Dark 2002 and Beyond, astro-ph/0204059 CERN-TH/2002-074.