Your search keyword '"Varentsov D"' showing total 8 results

1. Possible studies of explosively driven non-ideal plasma using a proton microscope at the Facility for Antiprotons and Ion Research

Author

Shilkin, N. S., Yuriev, D. S., Mintsev, V. B., Bogdanov, A. V., Kolesnikov, D. S., Skoblyakov, A. V., Kantsyrev, A. V., Golubev, A. A., Hoffmann, D. H. H., Varentsov, D. V., Shilkin, N. S., Yuriev, D. S., Mintsev, V. B., Bogdanov, A. V., Kolesnikov, D. S., Skoblyakov, A. V., Kantsyrev, A. V., Golubev, A. A., Hoffmann, D. H. H., and Varentsov, D. V.

Abstract

The article describes possible experiments with explosively driven non-ideal plasma at the proton microscope at the Facility for Antiprotons and Ion Research. It is proposed to employ linear explosive tubes for plasma generation and to measure an areal density in shock-compressed plasma of argon and xenon. The proposed experiments will provide valuable information on influence of strong interparticle interactions on thermodynamic properties of strongly coupled plasma. The density measurement will help the researchers to understand the nature of wall and wire precursors arising in the shock tubes.

Published

2024

2. Possible studies of explosively driven non-ideal plasma using a proton microscope at the Facility for Antiprotons and Ion Research

Author

Shilkin, N. S., Yuriev, D. S., Mintsev, V. B., Bogdanov, A. V., Kolesnikov, D. S., Skoblyakov, A. V., Kantsyrev, A. V., Golubev, A. A., Hoffmann, D. H. H., Varentsov, D. V., Shilkin, N. S., Yuriev, D. S., Mintsev, V. B., Bogdanov, A. V., Kolesnikov, D. S., Skoblyakov, A. V., Kantsyrev, A. V., Golubev, A. A., Hoffmann, D. H. H., and Varentsov, D. V.

Abstract

The article describes possible experiments with explosively driven non-ideal plasma at the proton microscope at the Facility for Antiprotons and Ion Research. It is proposed to employ linear explosive tubes for plasma generation and to measure an areal density in shock-compressed plasma of argon and xenon. The proposed experiments will provide valuable information on influence of strong interparticle interactions on thermodynamic properties of strongly coupled plasma. The density measurement will help the researchers to understand the nature of wall and wire precursors arising in the shock tubes.

Published

2024

3. Possible studies of explosively driven non-ideal plasma using a proton microscope at the Facility for Antiprotons and Ion Research

Author

Shilkin, N. S., Yuriev, D. S., Mintsev, V. B., Bogdanov, A. V., Kolesnikov, D. S., Skoblyakov, A. V., Kantsyrev, A. V., Golubev, A. A., Hoffmann, D. H. H., Varentsov, D. V., Shilkin, N. S., Yuriev, D. S., Mintsev, V. B., Bogdanov, A. V., Kolesnikov, D. S., Skoblyakov, A. V., Kantsyrev, A. V., Golubev, A. A., Hoffmann, D. H. H., and Varentsov, D. V.

Abstract

The article describes possible experiments with explosively driven non-ideal plasma at the proton microscope at the Facility for Antiprotons and Ion Research. It is proposed to employ linear explosive tubes for plasma generation and to measure an areal density in shock-compressed plasma of argon and xenon. The proposed experiments will provide valuable information on influence of strong interparticle interactions on thermodynamic properties of strongly coupled plasma. The density measurement will help the researchers to understand the nature of wall and wire precursors arising in the shock tubes.

Published

2024

4. Possible studies of explosively driven non-ideal plasma using a proton microscope at the Facility for Antiprotons and Ion Research

Author

Shilkin, N. S., Yuriev, D. S., Mintsev, V. B., Bogdanov, A. V., Kolesnikov, D. S., Skoblyakov, A. V., Kantsyrev, A. V., Golubev, A. A., Hoffmann, D. H. H., Varentsov, D. V., Shilkin, N. S., Yuriev, D. S., Mintsev, V. B., Bogdanov, A. V., Kolesnikov, D. S., Skoblyakov, A. V., Kantsyrev, A. V., Golubev, A. A., Hoffmann, D. H. H., and Varentsov, D. V.

Abstract

The article describes possible experiments with explosively driven non-ideal plasma at the proton microscope at the Facility for Antiprotons and Ion Research. It is proposed to employ linear explosive tubes for plasma generation and to measure an areal density in shock-compressed plasma of argon and xenon. The proposed experiments will provide valuable information on influence of strong interparticle interactions on thermodynamic properties of strongly coupled plasma. The density measurement will help the researchers to understand the nature of wall and wire precursors arising in the shock tubes.

Published

2024

5. High-energy-density-science capabilities at the Facility for Antiproton and Ion Research

Author

Schoenberg, K, Schoenberg, K, Bagnoud, V, Blazevic, A, Fortov, VE, Gericke, DO, Golubev, A, Hoffmann, DHH, Kraus, D, Lomonosov, IV, Mintsev, V, Neff, S, Neumayer, P, Piriz, AR, Redmer, R, Rosmej, O, Roth, M, Schenkel, T, Sharkov, B, Tahir, NA, Varentsov, D, Zhao, Y, Schoenberg, K, Schoenberg, K, Bagnoud, V, Blazevic, A, Fortov, VE, Gericke, DO, Golubev, A, Hoffmann, DHH, Kraus, D, Lomonosov, IV, Mintsev, V, Neff, S, Neumayer, P, Piriz, AR, Redmer, R, Rosmej, O, Roth, M, Schenkel, T, Sharkov, B, Tahir, NA, Varentsov, D, and Zhao, Y

Abstract

The Facility for Antiproton and Ion Research (FAIR) will employ the World's highest intensity relativistic beams of heavy nuclei to uniquely create and investigate macroscopic (millimeter-sized) quantities of highly energetic and dense states of matter. Four principal themes of research have been identified: properties of materials driven to extreme conditions of pressure and temperature, shocked matter and material equation of state, basic properties of strongly coupled plasma and warm dense matter, and nuclear photonics with a focus on the excitation of nuclear processes in plasmas, laser-driven particle acceleration, and neutron production. The research program, principally driven by an international collaboration of scientists, called the HED@FAIR collaboration, will evolve over the next decade as the FAIR project completes and experimental capabilities develop. The first programmatic research element, called "FAIR Phase 0, officially began in 2018 to test components, detectors, and experimental techniques. Phase-0 research employs the existing and enhanced infrastructure of the GSI Helmholtzzentrum für Schwerionenforschung (GSI) heavy-ion synchrotron coupled with the PHELIX high-energy, high-intensity laser. The "FAIR Day one" experimental program, presently scheduled to begin in 2025, commences the use of FAIR's heavy-ion synchrotron, coupled to new experimental and diagnostic infrastructure, to realize the envisaged high-energy-density-science research program.

Published

2020

6. High-energy-density-science capabilities at the Facility for Antiproton and Ion Research

Author

Schoenberg, K, Schoenberg, K, Bagnoud, V, Blazevic, A, Fortov, VE, Gericke, DO, Golubev, A, Hoffmann, DHH, Kraus, D, Lomonosov, IV, Mintsev, V, Neff, S, Neumayer, P, Piriz, AR, Redmer, R, Rosmej, O, Roth, M, Schenkel, T, Sharkov, B, Tahir, NA, Varentsov, D, Zhao, Y, Schoenberg, K, Schoenberg, K, Bagnoud, V, Blazevic, A, Fortov, VE, Gericke, DO, Golubev, A, Hoffmann, DHH, Kraus, D, Lomonosov, IV, Mintsev, V, Neff, S, Neumayer, P, Piriz, AR, Redmer, R, Rosmej, O, Roth, M, Schenkel, T, Sharkov, B, Tahir, NA, Varentsov, D, and Zhao, Y

Abstract

The Facility for Antiproton and Ion Research (FAIR) will employ the World's highest intensity relativistic beams of heavy nuclei to uniquely create and investigate macroscopic (millimeter-sized) quantities of highly energetic and dense states of matter. Four principal themes of research have been identified: properties of materials driven to extreme conditions of pressure and temperature, shocked matter and material equation of state, basic properties of strongly coupled plasma and warm dense matter, and nuclear photonics with a focus on the excitation of nuclear processes in plasmas, laser-driven particle acceleration, and neutron production. The research program, principally driven by an international collaboration of scientists, called the HED@FAIR collaboration, will evolve over the next decade as the FAIR project completes and experimental capabilities develop. The first programmatic research element, called "FAIR Phase 0, officially began in 2018 to test components, detectors, and experimental techniques. Phase-0 research employs the existing and enhanced infrastructure of the GSI Helmholtzzentrum für Schwerionenforschung (GSI) heavy-ion synchrotron coupled with the PHELIX high-energy, high-intensity laser. The "FAIR Day one" experimental program, presently scheduled to begin in 2025, commences the use of FAIR's heavy-ion synchrotron, coupled to new experimental and diagnostic infrastructure, to realize the envisaged high-energy-density-science research program.

Published

2020

7. The High-Energy-Density Physics at FAIR Collaboration: Unique Capabilities for HEDM Science

Author

Schoenberg, K., Bagnoud, V., Blazevic, A., Fortov, V. E., Gericke, D. O., Golubev, A., Hoffmann, D. H. H., (0000-0002-6350-4180) Kraus, D., Lomonosov, I. V., Mintsev, V., Neff, S., Neumayer, P., Piriz, A. R., Redmer, R., Rosmej, O., Roth, M., Schenkel, T., Tahir, N. A., Varentsov, D., Zhao, Y., Schoenberg, K., Bagnoud, V., Blazevic, A., Fortov, V. E., Gericke, D. O., Golubev, A., Hoffmann, D. H. H., (0000-0002-6350-4180) Kraus, D., Lomonosov, I. V., Mintsev, V., Neff, S., Neumayer, P., Piriz, A. R., Redmer, R., Rosmej, O., Roth, M., Schenkel, T., Tahir, N. A., Varentsov, D., and Zhao, Y.

Abstract

The High-Energy-Density Science collaboration at the Facility for Antiproton and Ion Research (HED@FAIR) will utilize the World’s highest intensity relativistic beams of heavy nuclei to uniquely create and investigate highly energetic and dense-plasma states of cubic millimeter sized matter for durations of approximately 100 ns. Four principal themes of research have been identified by the HED@FAIR collaboration: Properties of materials driven to extreme conditions of pressure and temperatures, Shocked matter and material equation of state (EOS), Basic properties of strongly-coupled plasma and warm dense matter, and Nuclear photonics with a focus on the excitation of nuclear processes in plasmas, laser-driven particle acceleration, and neutron production. Collaboration research will develop over the next decade as the FAIR project is completed and the heavy ion beam and experimental capabilities evolve. The so-called "FAIR Phase 0" experiments officially began in 2018 to test the components and detectors prepared for FAIR. The HEDM Phase-0 research effort will utilize the existing and enhanced GSI infrastructure of the SIS-18 synchrotron coupled with the PHELIX laser. The FAIR experimental program, presently scheduled to begin in 2025, will commence the use of the SIS-100 synchrotron coupled with new experimental and diagnostic infrastructure to realize the envisaged unique HEDM research program.

Published

2020

8. APPA at FAIR : From fundamental to applied research

Author

Stoehlker, Th., Bagnoud, V., Blaum, K., Blazevic, A., Braeuning-Demian, A., Durante, M., Herfurth, F., Lestinsky, M., Litvinov, Y., Neff, S., Pleskac, R., Schuch, Reinhold, Schippers, S., Severin, D., Tauschwitz, A., Trautmann, C., Varentsov, D., Widmann, E., Stoehlker, Th., Bagnoud, V., Blaum, K., Blazevic, A., Braeuning-Demian, A., Durante, M., Herfurth, F., Lestinsky, M., Litvinov, Y., Neff, S., Pleskac, R., Schuch, Reinhold, Schippers, S., Severin, D., Tauschwitz, A., Trautmann, C., Varentsov, D., and Widmann, E.

Abstract

FAIR with its intense beams of ions and antiprotons provides outstanding and worldwide unique experimental conditions for extreme matter research in atomic and plasma physics and for application oriented research in biophysics, medical physics and materials science. The associated research programs comprise interaction of matter with highest electromagnetic fields, properties of plasmas and of solid matter under extreme pressure, density, and temperature conditions, simulation of galactic cosmic radiation, research in nanoscience and charged particle radiotherapy. A broad variety of APPA-dedicated facilities including experimental stations, storage rings, and traps, equipped with most sophisticated instrumentation will allow the APPA community to tackle new challenges. The worldwide most intense source of slow antiprotons will expand the scope of APPA related research to the exciting field of antimatter.

Published

2015