Abstract

Based on a magnetically compressed discharge with an electromagnet, a high-power plasma radiator capable of operating in the pulsed, continuous, and combined regimes has been created. The radiant exitance of the discharge plasma reaches 2×10<sup>5</sup>W/cm<sup>2</sup> in the pulsed regime and 10<sup>4</sup>W/cm<sup>2</sup> in the continuous regime.

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  1. G. G. Vorypaev, I. S. Mironov, I. V. Podmoshenskiĭ, and P. N. Rogovtsev, “Experimental study of a high-current magnetic-compression discharge,” in Collection of Materials of the First All-Union Seminar on the Dynamics of High-Current Arc Discharge in a Magnetic Field, Novosibirsk, Institute of Thermal Physics, Siberian Section, Academy of Sciences of the USSR, 1990, pp. 140-145.
  2. E. V. Kalachnikov, I. S. Mironov, P. N. Rogovtsev, L. A. Pavlova, and I. V. Podmoshenskiĭ, “Study of the radiation dynamics of a high-current magnetic-compression discharge,” Teplofiz. Vys. Temp. 2, 837 (1986).
  3. A. G. Bedrin, S. P. Dashuk, and I. S. Mironov, “Quasi-continuous radiation source based on a magnetic-compression discharge,” Teplofiz. Vys. Temp. 45, 182 (2007).
  4. L. D. Gorshkova, I. S. Mironov, and I. V. Podmoshenskiĭ, “Electromagnetic characteristics and energy balance of an H-compressed discharge,” Teplofiz. Vys. Temp. 16, 1130 (1978).
  5. I. S. Mironov and P. N. Rogovtsev, “Semiempirical model of a high-current magnetically compressed discharge,” in Collection of Abstracts of Reports of the Fourth InterState Symposium on Radiation Plasmodynamics, Moscow, MGTU, 1997, pp. 140-141.
  6. L. Spitzer, Physics of Fully Ionized Gases (Interscience, New York, 1962; Mir, Moscow, 1965).

2007 (1)

A. G. Bedrin, S. P. Dashuk, and I. S. Mironov, “Quasi-continuous radiation source based on a magnetic-compression discharge,” Teplofiz. Vys. Temp. 45, 182 (2007).

1986 (1)

E. V. Kalachnikov, I. S. Mironov, P. N. Rogovtsev, L. A. Pavlova, and I. V. Podmoshenskiĭ, “Study of the radiation dynamics of a high-current magnetic-compression discharge,” Teplofiz. Vys. Temp. 2, 837 (1986).

1978 (1)

L. D. Gorshkova, I. S. Mironov, and I. V. Podmoshenskiĭ, “Electromagnetic characteristics and energy balance of an H-compressed discharge,” Teplofiz. Vys. Temp. 16, 1130 (1978).

Bedrin, A. G.

A. G. Bedrin, S. P. Dashuk, and I. S. Mironov, “Quasi-continuous radiation source based on a magnetic-compression discharge,” Teplofiz. Vys. Temp. 45, 182 (2007).

Dashuk, S. P.

A. G. Bedrin, S. P. Dashuk, and I. S. Mironov, “Quasi-continuous radiation source based on a magnetic-compression discharge,” Teplofiz. Vys. Temp. 45, 182 (2007).

Gorshkova, L. D.

L. D. Gorshkova, I. S. Mironov, and I. V. Podmoshenskiĭ, “Electromagnetic characteristics and energy balance of an H-compressed discharge,” Teplofiz. Vys. Temp. 16, 1130 (1978).

Kalachnikov, E. V.

E. V. Kalachnikov, I. S. Mironov, P. N. Rogovtsev, L. A. Pavlova, and I. V. Podmoshenskiĭ, “Study of the radiation dynamics of a high-current magnetic-compression discharge,” Teplofiz. Vys. Temp. 2, 837 (1986).

Mironov, I. S.

A. G. Bedrin, S. P. Dashuk, and I. S. Mironov, “Quasi-continuous radiation source based on a magnetic-compression discharge,” Teplofiz. Vys. Temp. 45, 182 (2007).

E. V. Kalachnikov, I. S. Mironov, P. N. Rogovtsev, L. A. Pavlova, and I. V. Podmoshenskiĭ, “Study of the radiation dynamics of a high-current magnetic-compression discharge,” Teplofiz. Vys. Temp. 2, 837 (1986).

L. D. Gorshkova, I. S. Mironov, and I. V. Podmoshenskiĭ, “Electromagnetic characteristics and energy balance of an H-compressed discharge,” Teplofiz. Vys. Temp. 16, 1130 (1978).

I. S. Mironov and P. N. Rogovtsev, “Semiempirical model of a high-current magnetically compressed discharge,” in Collection of Abstracts of Reports of the Fourth InterState Symposium on Radiation Plasmodynamics, Moscow, MGTU, 1997, pp. 140-141.

G. G. Vorypaev, I. S. Mironov, I. V. Podmoshenskiĭ, and P. N. Rogovtsev, “Experimental study of a high-current magnetic-compression discharge,” in Collection of Materials of the First All-Union Seminar on the Dynamics of High-Current Arc Discharge in a Magnetic Field, Novosibirsk, Institute of Thermal Physics, Siberian Section, Academy of Sciences of the USSR, 1990, pp. 140-145.

Pavlova, L. A.

E. V. Kalachnikov, I. S. Mironov, P. N. Rogovtsev, L. A. Pavlova, and I. V. Podmoshenskiĭ, “Study of the radiation dynamics of a high-current magnetic-compression discharge,” Teplofiz. Vys. Temp. 2, 837 (1986).

Podmoshenskii, I. V.

E. V. Kalachnikov, I. S. Mironov, P. N. Rogovtsev, L. A. Pavlova, and I. V. Podmoshenskiĭ, “Study of the radiation dynamics of a high-current magnetic-compression discharge,” Teplofiz. Vys. Temp. 2, 837 (1986).

L. D. Gorshkova, I. S. Mironov, and I. V. Podmoshenskiĭ, “Electromagnetic characteristics and energy balance of an H-compressed discharge,” Teplofiz. Vys. Temp. 16, 1130 (1978).

G. G. Vorypaev, I. S. Mironov, I. V. Podmoshenskiĭ, and P. N. Rogovtsev, “Experimental study of a high-current magnetic-compression discharge,” in Collection of Materials of the First All-Union Seminar on the Dynamics of High-Current Arc Discharge in a Magnetic Field, Novosibirsk, Institute of Thermal Physics, Siberian Section, Academy of Sciences of the USSR, 1990, pp. 140-145.

Rogovtsev, P. N.

E. V. Kalachnikov, I. S. Mironov, P. N. Rogovtsev, L. A. Pavlova, and I. V. Podmoshenskiĭ, “Study of the radiation dynamics of a high-current magnetic-compression discharge,” Teplofiz. Vys. Temp. 2, 837 (1986).

G. G. Vorypaev, I. S. Mironov, I. V. Podmoshenskiĭ, and P. N. Rogovtsev, “Experimental study of a high-current magnetic-compression discharge,” in Collection of Materials of the First All-Union Seminar on the Dynamics of High-Current Arc Discharge in a Magnetic Field, Novosibirsk, Institute of Thermal Physics, Siberian Section, Academy of Sciences of the USSR, 1990, pp. 140-145.

I. S. Mironov and P. N. Rogovtsev, “Semiempirical model of a high-current magnetically compressed discharge,” in Collection of Abstracts of Reports of the Fourth InterState Symposium on Radiation Plasmodynamics, Moscow, MGTU, 1997, pp. 140-141.

Spitzer, L.

L. Spitzer, Physics of Fully Ionized Gases (Interscience, New York, 1962; Mir, Moscow, 1965).

Vorypaev, G. G.

G. G. Vorypaev, I. S. Mironov, I. V. Podmoshenskiĭ, and P. N. Rogovtsev, “Experimental study of a high-current magnetic-compression discharge,” in Collection of Materials of the First All-Union Seminar on the Dynamics of High-Current Arc Discharge in a Magnetic Field, Novosibirsk, Institute of Thermal Physics, Siberian Section, Academy of Sciences of the USSR, 1990, pp. 140-145.

Teplofiz. Vys. Temp. (3)

E. V. Kalachnikov, I. S. Mironov, P. N. Rogovtsev, L. A. Pavlova, and I. V. Podmoshenskiĭ, “Study of the radiation dynamics of a high-current magnetic-compression discharge,” Teplofiz. Vys. Temp. 2, 837 (1986).

A. G. Bedrin, S. P. Dashuk, and I. S. Mironov, “Quasi-continuous radiation source based on a magnetic-compression discharge,” Teplofiz. Vys. Temp. 45, 182 (2007).

L. D. Gorshkova, I. S. Mironov, and I. V. Podmoshenskiĭ, “Electromagnetic characteristics and energy balance of an H-compressed discharge,” Teplofiz. Vys. Temp. 16, 1130 (1978).

Other (3)

I. S. Mironov and P. N. Rogovtsev, “Semiempirical model of a high-current magnetically compressed discharge,” in Collection of Abstracts of Reports of the Fourth InterState Symposium on Radiation Plasmodynamics, Moscow, MGTU, 1997, pp. 140-141.

L. Spitzer, Physics of Fully Ionized Gases (Interscience, New York, 1962; Mir, Moscow, 1965).

G. G. Vorypaev, I. S. Mironov, I. V. Podmoshenskiĭ, and P. N. Rogovtsev, “Experimental study of a high-current magnetic-compression discharge,” in Collection of Materials of the First All-Union Seminar on the Dynamics of High-Current Arc Discharge in a Magnetic Field, Novosibirsk, Institute of Thermal Physics, Siberian Section, Academy of Sciences of the USSR, 1990, pp. 140-145.

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