Your search keyword '"Varentsov D"' showing total 4 results

1. High energy density physics generated by intense heavy ion beams.

Author

Hoffmann, D., Fortov, V., Kuster, M., Mintsev, V., Sharkov, B., Tahir, N., Udrea, S., Varentsov, D., and Weyrich, K.

Subjects

HEAVY ions, ION bombardment, DENSE plasma focus, PARTICLES (Nuclear physics), ENERGY dissipation, STELLAR atmospheres, LASER beams

Abstract

Intense ion beams from accelerators are now available to generate high energy density matter and to study astrophysical phenomena in the laboratory under controlled and reproducible conditions. A detailed understanding of interaction phenomena of intense ion- and laser radiation with matter is important for a large number of applications in different fields of science, extending from basic research of plasma properties to application in energy science and the investigation of processes occurring in stellar atmospheres or even in the interior of stars and planets. Energy loss processes of heavy ions in plasma and cold matter are important for the generation of high energy density states in general and especially in the hot dense plasma of an inertial fusion target. Of special interest are phase transitions and the associated time scales when matter passes the warm dense matter regime of the phase diagram at high density but relatively low temperature. We present an overview on recent results and developments of beam plasma, and beam matter interaction processes studied with heavy ion beams and laser beams combined with accelerator and nuclear physics technology. A natural example of hot dense plasma is provided by our neighbouring star the sun, and allows a deep insight into the physics of fusion, the properties of matter at high energy density, and is moreover an excellent laboratory for astroparticle physics. As such the sun’s interior plasma can even be used to probe the existence of novel particles and dark matter candidates with a combination of equipment and methods from accelerator technology and high resolution plasma spectroscopy. [ABSTRACT FROM AUTHOR]

Published

2009

2. HIGH ENERGY DENSITY PHYSICS WITH INTENSE PARTICLE AND LASER BEAMS.

Author

HOFFMANN, D. H. H., BLAZEVIC, A., TAHIR, N. A., UDREA, S., VARENTSOV, D., and ZHAO, Y.

Subjects

LASER beams, ION bombardment, PHASE transitions, ENERGY dissipation, PROPERTIES of matter

Abstract

Interaction of intense ion radiation with matter has numerous applications in different fields of science, ranging from basic research of plasma properties to application in energy science. Energy loss processes of heavy ions in plasma and cold matter are important to understand the generation of high energy density states in matter. The hot dense plasma of an inertial fusion target is just one example. Of special interest are phase transitions, when irradiated matter passes through the parameter regime of warm dense matter, which is located in the phase diagram at high density but relatively low temperature. Typical parameters are in the pressure range of kbar to Mbar and temperatures ranging into the few eV regime. We present an overview on recent results and developments of beam plasma, and beam matter interaction processes studied with heavy ion beams from the GSI accelerator facilities, which consist of an rf-accelerator (UNILAC: Universal Linear Accelerator), a heavy ion synchrotron (SIS 18) and an experimental storage ring (ESR). The synchrotron SIS18 currently delivers an intense uranium beam that deposits about 1 kJ/g specific energy in solid matter. Using this beam, high energy density states close to the critical point of lead, have been reached and solid lead foils have been heated to a measured brightness temperature on the order of 5000 K. [ABSTRACT FROM AUTHOR]

Published

2009

3. Particle accelerator physics and technology for high energy density physics research.

Author

Hoffmann, D. H.H., Blazevic, A., Rosmej, O. N., Spiller, P., Tahir, N. A., Weyrich, K., Dafni, T., Kuster, M., Ni, P., Roth, M., Udrea, S., Varentsov, D., Jacoby, J., Kain, V., Schmidt, R., Zioutas, K., Mintsev, V., Fortov, V. E., and Sharkov, B. Yu.

Subjects

PARTICLE accelerators, PHYSICS, LASER beams, INERTIAL confinement fusion, SYNCHROTRONS

Abstract

Interaction phenomena of intense ion- and laser radiation with matter have a large range of application in different fields of science, extending from basic research of plasma properties to applications in energy science, especially in inertial fusion. The heavy ion synchrotron at GSI now routinely delivers intense uranium beams that deposit about 1 kJ/g of specific energy in solid matter, e.g. solid lead. Our simulations show that the new accelerator complex FAIR (Facility for Antiproton and Ion Research) at GSI as well as beams from the CERN large hadron collider (LHC) will vastly extend the accessible parameter range for high energy density states. A natural example of hot dense plasma is provided by our neighbouring star the sun, and allows a deep insight into the physics of fusion, the properties of matter at high energy density, and is moreover an excellent laboratory for astroparticle physics. As such the sun's interior plasma can even be used to probe the existence of novel particles and dark matter candidates. We present an overview on recent results and developments of dense plasma physics addressed with heavy ion and laser beams combined with accelerator- and nuclear physics technology. [ABSTRACT FROM AUTHOR]

Published

2007

4. Density measurements of heavy-ion-beam-induced stress waves in solid matter by a sensitive laser deflection technique.

Author

Constantin, C., Niemann, C., Dewald, E., Udrea, S., Jacoby, J., Varentsov, D., Schwab, P., Wieser, J., and Hoffman, D. H. H.

Subjects

LASER beams, REFRACTIVE index, STRESS waves, ELASTIC waves, INTERFEROMETERS, OPTICAL instruments

Abstract

We present a sensitive density diagnostic based on the deflection of a laser beam by refractive index gradients. The method is used to investigate stress waves in plexiglass, created by the irradiation of multilayered metal–plexiglass targets with intense relativistic heavy-ion beams. Measured laser deflection angles are of the order of 1 mrad, with a resolution of the apparatus of 50 μrad. Results are in excellent agreement with interferometric measurements. The deflection technique is superior to an imaging interferometer in terms of simplicity and sensitivity. © 2004 American Institute of Physics. [ABSTRACT FROM AUTHOR]

Published

2004