33.

Яненко Н.Н.

Метод дробных шагов решения многомерных задач математиче-

ской физики. Новосибирск: Наука, 1967.

REFERENCES

[1] Cherepashchuk A.M. SS 433: New results, new problems.

Zemlya i Vselennaya

[The

Earth and the Universe], 1986, no. 1, pp. 21–29 (in Russ.).

[2] Beskin V.S. Magnetohydrodynamic models of astrophysical jet exhausts.

Physics-

Uspekhi

[Advances in Physical Sciences], 2010, no. 180 (12), pp. 1241–1278 (in

Russ.).

[3] Cherepashchuk A.M. Data of photometric observations SS433 and their

interpretation.

Itogi nauki i tekhniki. Ser. Astronomiya

[Totals of Science and

Technology, Astronomy], 1988, no. 38, pp. 60–120 (in Russ.).

[4] Margon B. Observations of SS433.

ARA&A

, 1984, iss. 22, pp. 507–536.

[5] Lauer T.R. Compact Core of Galaxy M87.

HST News Release

, 1991. STSCI-

PRC92-01.

[6] Mioduszewski A.J., Rupen M.P., Walker R.C. et al. A Summer of SS433: Forty Days

of VLBA Imaging.

Bull. Am. Astron. Soc.

, 2004, vol. 36, p. 967.

[7] Biretta J.A., Owen F.N. Velocity Structure of the M87 Jet: Preliminary Results; ed. by

J. Anton Zensus, Timothy J. Pearson.

Parsec-scale radio jets.

Cambridge University

Press, 1990, pp. 125–128.

[8] Cherepashchuk A.M. Observational Manifestations of Precession of Accretion Disk

in the SS 433 Binary System.

Space Science Reviews

, 2002, vol. 102 (1), pp. 23–35.

[9] Beskin V.S. Osesimmetrichnye statsionarnye techeniya v astrofizike [Axisymmetric

stationary flows in astrophysics]. Moscow, Editorial URSS Publ., 2006.

[10] Spruit H.C. Theory of Magnetically Powered Jets.

The jet paradigm: from

microquasars to quasars

, 2010, vol. 794, pp. 233–263.

[11] Bisnovatyi-Kogan G.S. Mechanisms of jet formation, ed. by L. Errico, A. Vittone.

Stellar jets and bipolar out ows.

Dordrecht: Kluwer Academic Publishers, 1993.

[12] Cerqueira A.H., de Gouveia Dal Pino E.M. Magnetic Field Effects on the Structure

and Evolution of Overdense Radiatively Cooling Jets.

Astrophys. J

., 1999, vol. 510,

pp. 828–845.

[13] Savel’ev V.V., Toropin Yu. M., Chechetkin V.M. Simulations of a Supersonic

Accretion onto Magnetized Disks: Properties of Developing Outflows.

Low Mass

Star Formation — from Infall to Outflow.

Poster proceedings of IAU Symp., ed. by

F. Malbet, A. Castets, 1997, vol. 182, pp. 254.

[14] Komissarov S.S. Magnetic Acceleration of Relativistic Jets.

Mem. S.A. It.,

2011,

vol. 82, pp. 95–103.

[15] Ouyed R., Pudritz R.E. Numerical Simulations of Astrophysical Jets from Keplerian

Disks. II. Episodic Outlows.

Astrophys. J

., 1997, vol. 484, pp. 794–809.

[16] Romanova M.M., Ustyugova G.V., Koldoba A.V., Lovelace R.V.E. Launching

of Conical Winds and Axial Jets from the Disk-Magnetosphere Boundary:

Axisymmetric and 3D Simulations.

MNRAS

, 2009, vol. 399, pp. 1802–1828.

[17] Galanin M.P., Lukin V.V., Chechetkin V.M. Jet Acceleration for Different Versions of

the Substance Source Simulation.

Matem. Modelirovanie

[Mathematical Simulation],

2011, vol. 23 (10), pp. 65–81 (in Russ.).

[18] Savel’ev V.V., Toropin Yu.M., Chechetkin V.M. A Possible Mechanism for the

Formation of Molecular Flows.

Astronomy Reports

, 1996, vol. 40, pp. 494–508.

[19] Fendt C. Formation of Protostellar Jets as Two-Component Out ows from Star-Disk

Magnetospheres.

Astrophys. J

., 2009, vol. 692, pp. 346–363.

[20] Galanin M.P., Toropin Yu.M., Chechetkin V.M. Radiative Acceleration of

the Substance Portions in Accretion Disks Nearby Astrophysical Objects

Astronomicheskiy zhurnal

[Astronomical Journal], 1999, iss. 76 (2), pp. 143–160

(in Russ.).

92

ISSN 1812-3368. Вестник МГТУ им. Н.Э. Баумана. Сер. “Естественные науки”. 2015. № 2