Your search keyword '"Varentsov D"' showing total 19 results

1. Advances of dense plasma physics with particle accelerators

Author

Hoffmann, D. H.H., Blazevic, A., Rosmej, O. N., Spiller, P., Tahir, N. A., Weyrich, K., Dafni, T., Kuster, M., Roth, M., Udrea, S., Varentsov, D., Jacoby, J., Zioutas, Sharkov, B. Yu., Hoffmann, D. H.H., Blazevic, A., Rosmej, O. N., Spiller, P., Tahir, N. A., Weyrich, K., Dafni, T., Kuster, M., Roth, M., Udrea, S., Varentsov, D., Jacoby, J., Zioutas, and Sharkov, B. Yu.

Abstract

High intensity particle beams from accelerators induce high energy density states in bulk matter. The SIS-18 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. Due to the specific nature of the ion-matter interaction a volume of matter is heated uniformly with low gradients of temperature and pressure in the initial phase, depending on the pulse structure of the beam with respect to space and time. 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. One special piece of accelerator equipment a superconducting high field dipole magnet, developed for the LHC at CERN is now serving as a key instrument to diagnose the dense plasma of the sun interior plasma, thus providing an extremely interesting combination of accelerator physics, plasma physics and astro-particle physics.

Published

2006

2. Studies of thermophysical properties of high-energy-density states in matter using intense heavy ion beams at the future FAIR accelerator facilities: The HEDgeHOB collaboration

Author

Tahir, N. A., Shutov, A., Lomonosov, I. V., Gryaznov, V., Deutsch, C., Fortov, V. E., Hoffmann, D. H.H., Ni, P., Piriz, A. R., Udrea, S., Varentsov, D., Wouchuk, G., Tahir, N. A., Shutov, A., Lomonosov, I. V., Gryaznov, V., Deutsch, C., Fortov, V. E., Hoffmann, D. H.H., Ni, P., Piriz, A. R., Udrea, S., Varentsov, D., and Wouchuk, G.

Abstract

Intense beams of energetic heavy ions are believed to be a very efficient and novel tool to create states of High-Energy-Density (HED) in matter. This paper shows with the help of numerical simulations that the heavy ion beams that will be generated at the future Facility for Antiprotons and Ion Research (FAIR)[W.F. Henning, Nucl. Instr. Meth. B 214, 211 (2004)] will allow one to use two different experimental schemes to study HED states in matter. First scheme named HIHEX (Heavy Ion Heating and EXpansion), will generate high-pressure, high-entropy states in matter by volumetric isochoric heating. The heated material will then be allowed to expand isentropically. Using this scheme, it will be possible to study important regions of the phase diagram that are either difficult to access or are even unaccessible using traditional methods of shock compression. The second scheme would allow one to achieve low-entropy compression of a sample material like hydrogen or water to produce conditions that are believed to exist in the interiors of the giant planets. This scheme is named LAPLAS (LAboratory PLAnetary Sciences).

Published

2006

3. Pyrometric system for temperature measurements of HED matter generated by intense heavy ion beams

Author

Ni, P., Hoffmann, D. H.H., Kulish, M., Nikolaev, D., Tahir, N. A., Udrea, S., Varentsov, D., Wahl, H., Ni, P., Hoffmann, D. H.H., Kulish, M., Nikolaev, D., Tahir, N. A., Udrea, S., Varentsov, D., and Wahl, H.

Abstract

Recent experiments performed on heating of matter using intense uranium beams generated by the heavy ion synchrotron, SIS18, at the Gesellschaft für Schwerionenforschung (GSI) Darmstadt, have shown that using the present beam parameters, one can achieve near critical states of lead. The beam intensity was $4\cdot10^9$ions per bunch that was 130 ns long while the particle energy was 350 AMeV. A fast 6-channel pyrometer has been developed at the GSI in collaboration with scientists from the Institute of Problems of Chemical Physics (IPCP), Chernogolovka, to measure the temperature of the heated material. Temperatures from 1500 K to 5000 K were recorded for metallic targets.

Published

2006

4. First biological images with high-energy proton microscopy.

Author

Varentsov, D., Bogdanov, A., Demidov, V.S., Golubev, A.A., Kantsyrev, A., Lang, P.M., Nikolaev, D.N., Markov, N., Natale, F., Shestov, L., Simoniello, P., Smirnov, G.N., and Durante, M.

Subjects

IMAGING systems in biology, PROTON therapy, PHYSIOLOGICAL effects of protons, RADIOSURGERY, STEREOTAXIC techniques, TISSUES

Abstract

Abstract: High-energy proton microscopy provides unique capabilities in penetrating radiography including the combination of high spatial resolution and field-of-view, dynamic range of density for measurements, and reconstructing density variations to less than 1% inside volumes and in situ environments. We have recently proposed to exploit this novel proton radiography technique for image-guided stereotactic particle radiosurgery. Results of a first test for imaging biological and tissue-equivalent targets with high-energy (800 MeV) proton microscopy are presented here. Although we used a proton microscope setup at ITEP (Moscow, Russia) optimized for fast dynamic experiments in material research, we could reach a spatial resolution of 150 μm with approximately 1010 protons per image. The potential of obtaining high-resolution online imaging of the target using a therapeutic proton beam in the GeV energy region suggests that high-energy proton microscopy may be used for image-guided proton radiosurgery. [Copyright &y& Elsevier]

Published

2013

5. Electrical resistivity of high energy density matter generated by high intensity heavy ion beams

Author

Udrea, S., Shilkin, N., Varentsov, D., Tahir, N. A., Bock, R., Constantin, C., Dewald, E., Fortov, V. E., Hoffmann, D. H.H., Jacoby, J., Kulish, M., Lomonosov, I., Mintsev, V., Ni, P., Nikolaev, D., Shutov, A., Udrea, S., Shilkin, N., Varentsov, D., Tahir, N. A., Bock, R., Constantin, C., Dewald, E., Fortov, V. E., Hoffmann, D. H.H., Jacoby, J., Kulish, M., Lomonosov, I., Mintsev, V., Ni, P., Nikolaev, D., and Shutov, A.

Abstract

Development of new diagnostic techniques allowed, during the past few years, for a first series of measurements on the electrical resistivity of heavy ion beam generated high energy density (HED) matter. The experimental investigations have been carried out at the HHT laboratory of the Plasma Physics Department of the Gesellschaft für Schwerionenforschung in Darmstadt. In this report we review the results of these experiments and discuss future experimental and theoretical work planned to be carried out within the framework of the HEDgeHOB collaboration for precise determination of the electrical resistivity of HED matter.

Published

2006

6. Design, development, and testing of non-intercepting profile diagnostics for intense heavy ion beams using a capacitive pickup and beam induced gas fluorescence monitors

Author

BECKER, F., HUG, A., FORCK, P., KULISH, M., NI, P., UDREA, S., and VARENTSOV, D.

Abstract

An intense and focused heavy ion beam is a suitable tool to generate high energy density in matter. To compare results with simulations it is essential to know beam parameters as intensity, longitudinal, and transversal profile at the focal plane. Since the beams energy deposition will melt and evaporate even tungsten, non-intercepting diagnostics are required. Therefore a capacitive pickup with high resolution in both time and space was designed, built and tested at the high temperature experimental area at GSI. Additionally a beam induced fluorescence monitor was investigated for the synchrotrons (SIS-18) energy-regime (60–750 AMeV) and successfully tested in a beam-transfer-line.

Published

2006

7. Design, development, and testing of non-intercepting profile diagnostics for intense heavy ion beams using a capacitive pickup and beam induced gas fluorescence monitors

Author

BECKER, F., HUG, A., FORCK, P., KULISH, M., NI, P., UDREA, S., and VARENTSOV, D.

Abstract

An intense and focused heavy ion beam is a suitable tool to generate high energy density in matter. To compare results with simulations it is essential to know beam parameters as intensity, longitudinal, and transversal profile at the focal plane. Since the beam's energy deposition will melt and evaporate even tungsten, non-intercepting diagnostics are required. Therefore a capacitive pickup with high resolution in both time and space was designed, built and tested at the high temperature experimental area at GSI. Additionally a beam induced fluorescence monitor was investigated for the synchrotron's (SIS-18) energy-regime (60–750 AMeV) and successfully tested in a beam-transfer-line.

Published

2006

8. Studies of thermophysical properties of high-energy-density states in matter using intense heavy ion beams at the future FAIR accelerator facilities: The HEDgeHOB collaboration

Author

Tahir, N., Shutov, A., Lomonosov, I., Gryaznov, V., Deutsch, C., Fortov, V., Hoffmann, D., IN, P., Piriz, A., Udrea, S., Varentsov, D., and Wouchuk, G.

Abstract

Intense beams of energetic heavy ions are believed to be a very efficient and novel tool to create states of High-Energy-Density (HED) in matter. This paper shows with the help of numerical simulations that the heavy ion beams that will be generated at the future Facility for Antiprotons and Ion Research (FAIR)[W.F.?Henning, Nucl. Instr. Meth. B 214, 211 (2004)] will allow one to use two different experimental schemes to study HED states in matter. First scheme named HIHEX (Heavy Ion Heating and EXpansion), will generate high-pressure, high-entropy states in matter by volumetric isochoric heating. The heated material will then be allowed to expand isentropically. Using this scheme, it will be possible to study important regions of the phase diagram that are either difficult to access or are even unaccessible using traditional methods of shock compression. The second scheme would allow one to achieve low-entropy compression of a sample material like hydrogen or water to produce conditions that are believed to exist in the interiors of the giant planets. This scheme is named LAPLAS (LAboratory PLAnetary Sciences).

Published

2006

9. Pyrometric system for temperature measurements of HED matter generated by intense heavy ion beams

Author

IN, P., Hoffmann, D., Kulish, M., Nikolaev, D., Tahir, N., Udrea, S., Varentsov, D., and Wahl, H.

Abstract

Recent experiments performed on heating of matter using intense uranium beams generated by the heavy ion synchrotron, SIS18, at the Gesellschaft f?r Schwerionenforschung (GSI) Darmstadt, have shown that using the present beam parameters, one can achieve near critical states of lead. The beam intensity was 4.109 ions per bunch that was 130?ns long while the particle energy was 350?AMeV. A fast 6-channel pyrometer has been developed at the GSI in collaboration with scientists from the Institute of Problems of Chemical Physics (IPCP), Chernogolovka, to measure the temperature of the heated material. Temperatures from 1500?K to 5000?K were recorded for metallic targets.

Published

2006

10. Advances of dense plasma physics with particle accelerators

Author

Hoffmann, D., Blazevic, A., Rosmej, O., Spiller, P., Tahir, N., Weyrich, K., Dafni, T., Kuster, M., Roth, M., Udrea, S., Varentsov, D., Jacoby, J., Zioutas, and Sharkov, B.

Abstract

High intensity particle beams from accelerators induce high energy density states in bulk matter. The SIS-18 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. Due to the specific nature of the ion-matter interaction a volume of matter is heated uniformly with low gradients of temperature and pressure in the initial phase, depending on the pulse structure of the beam with respect to space and time. 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. One special piece of accelerator equipment a superconducting high field dipole magnet, developed for the LHC at CERN is now serving as a key instrument to diagnose the dense plasma of the sun interior plasma, thus providing an extremely interesting combination of accelerator physics, plasma physics and astro-particle physics.

Published

2006

11. Present and future perspectives for high energy density physics with intense heavy ion and laser beams

Author

HOFFMANN, D.H.H., BLAZEVIC, A., NI, P., ROSMEJ, O., ROTH, M., TAHIR, N.A., TAUSCHWITZ, A., UDREA, S., VARENTSOV, D., WEYRICH, K., and MARON, Y.

Abstract

Intense heavy ion beams from the Gesellschaft für Schwerionenforschung (GSI, Darmstadt, Germany) accelerator facilities, together with two high energy laser systems: petawatt high energy laser for ion experiments (PHELIX) and nanosecond high energy laser for ion experiments (NHELIX) are a unique combination to facilitate pioneering beam-plasma interaction experiments, to generate and probe high-energy-density (HED) matter and to address basic physics issues associated with heavy ion driven inertial confinement fusion. In one class of experiments, the laser will be used to generate plasma and the ion beam will be used to study the energy loss of energetic ions in ionized matter, and to probe the physical state of the laser-generated plasma. In another class of experiments, the intense heavy ion beam will be employed to create a sample of HED matter and the laser beam, together with other diagnostic tools, will be used to explore the properties of these exotic states of matter. The existing heavy ion synchrotron facility, SIS18, deliver an intense uranium beam that deposit about 1 kJ/g specific energy in solid matter. Using this beam, experiments have recently been performed where solid lead foils had been heated and a brightness temperature on the order of 5000 K was measured, using a fast multi-channel pyrometer that has been developed jointly by GSI and IPCP Chernogolovka. It is expected that the future heavy ion facility, facility for antiprotons and ion research (FAIR) will provide compressed beam pulses with an intensity that exceeds the current beam intensities by three orders of magnitude. This will open up the possibility to explore the thermophysical and transport properties of HED matter in a regime that is very difficult to access using the traditional methods of shock compression. Beam plasma interaction experiments using dense plasmas with a Γ-parameter between 0.5 and 1.5 have also been carried out. This dense Ar-plasma was generated by explosively driven shockwaves and showed enhanced energy loss for Xe and Ar ions in the energy range between 5.9 to 11.4 MeV.

Published

2005

12. Target heating in high-energy-density matter experiments at the proposed GSI FAIR facility: Non-linear bunch rotation in SIS100 and optimization of spot size and pulse length

Author

TAHIR, N.A., UDREA, S., DEUTSCH, C., FORTOV, V.E., GRANDJOUAN, N., GRYAZNOV, V., HOFFMANN, D.H.H., HÜLSMANN, P., KIRK, M., LOMONOSOV, I.V., PIRIZ, A.R., SHUTOV, A., SPILLER, P., TEMPORAL, M., and VARENTSOV, D.

Abstract

The Gesellschaft für Schwerionenforschung (GSI) Darmstadt has been approved to build a new powerful facility named FAIR (Facility for Antiprotons and Ion Research) which involves the construction of a new synchrotron ring SIS100. In this paper, we will report on the results of a parameter study that has been carried out to estimate the minimum pulse lengths and the maximum peak powers achievable, using bunch rotation RF gymnastic-including nonlinearities of the RF gap voltage in SIS100, using a longitudinal dynamics particle in cell (PIC) code, ESME. These calculations have shown that a pulse length of the order of 20 ns may be possible when no prebunching is performed while the pulse length gradually increases with the prebunching voltage. Three different cases, including 0.4 GeV/u, 1 GeV/u, and 2.7 GeV/u are considered for the particle energy. The worst case is for the kinetic energy of 0.4 GeV/u which leads to a pulse length of about 100 ns for a prebunching voltage of 100 kV (RF amplitude). The peak power was found to have a maximum, however, at 0.5–1.5kV prebunching voltage, depending on the mean kinetic energy of the ions. It is expected that the SIS100 will deliver a beam with an intensity of 1–2 × 1012 ions. Availability of such a powerful beam will make it possible to study the properties of high-energy-density (HED) matter in a parameter range that is very difficult to access by other means. These studies involve irradiation of high density targets by the ion beam for which optimization of the target heating is the key problem. The temperature to which a target can be heated depends on the power that is deposited in the material by the projectile ions. The optimization of the power, however, depends on the interplay of various parameters including beam intensity, beam spot area, and duration of the ion bunch. The purpose of this paper is to determine a set of the above parameters that would lead to an optimized target heating by the future SIS100 beam.

Published

2004

13. Cold compression of solid matter by intense heavy-ion-beam-generated pressure waves

Author

CONSTANTIN, C., DEWALD, E., NIEMANN, C., HOFFMANN, D.H.H, UDREA, S., VARENTSOV, D., JACOBY, J., FUNK, U.N., NEUNER, U., and TAUSCHWITZ, A.

Abstract

Experimental investigations of heavy-ion-generated shock waves in solid, multilayered targets were performed by applying a Schlieren and a laser-deflection technique. Shock velocity and the corresponding pressures, temporal and spatial density profiles inside the material compressed by multiple shock waves, and details of the shock dynamics were determined. Important for equation-of-state and phase transition studies, such experiments extend their relevance to inertial confinement fusion and astrophysical fundamental research.

Published

2004

14. High-energy-density matter research at GSI Darmstadt using intense heavy ion beams

Author

TAHIR, N.A., SHUTOV, A., VARENTSOV, D., HOFFMANN, D.H.H., SPILLER, P., LOMONOSOV, I., WIESER, J., JACOBY, J., and FORTOV, V.E.

Abstract

This paper presents two-dimensional numerical simulations of heating of matter with intense heavy ion beams. It has been shown that it is very advantageous to irradiate the target with two different beams simultaneously, a main high intensity bunched beam of a heavy element like uranium and an unbunched low intensity beam of a lighter element like argon. The main beam is used to heat the target while the second beam is used as a diagnostic tool. Influence of the shape of the focal spot on compression and heating of matter has also been studied using an elliptic focal spot with an ellipticity of 1.5 (semimajor axis is along y-axis and is 1.5 times the semiminor axis which is along x-axis). It has been found that the temporal behavior of the development of density, pressure, and temperature profiles along different directions is quite different, which is not the case with a circular focal spot.

Published

2002

15. Energy loss dynamics of intense heavy ion beams interacting with solid targets

Author

VARENTSOV, D., SPILLER, P., TAHIR, N.A., HOFFMANN, D.H.H., CONSTANTIN, C., DEWALD, E., JACOBY, J., LOMONOSOV, I.V., NEUNER, U., SHUTOV, A., WIESER, J., UDREA, S., and BOCK, R.

Abstract

At the Gesellschaft für Schwerionenforschung (GSI, Darmstadt) intense beams of energetic heavy ions have been used to generate high-energy-density (HED) state in matter by impact on solid targets. Recently, we have developed a new method by which we use the same heavy ion beam that heats the target to provide information about the physical state of the interior of the target (Varentsov et al., 2001). This is accomplished by measuring the energy loss dynamics (ELD) of the beam emerging from the back surface of the target. For this purpose, a new time-resolving energy loss spectrometer (scintillating Bragg-peak (SBP) spectrometer) has been developed. In our experiments we have measured energy loss dynamics of intense beams of 238U, 86Kr, 40Ar, and 18O ions during the interaction with solid rare-gas targets, such as solid Ne and solid Xe. We observed continuous reduction in the energy loss during the interaction time due to rapid hydrodynamic response of the ion-beam-heated target matter. These are the first measurements of this kind. Two-dimensional hydrodynamic simulations were carried out using the beam and target parameters of the experiments. The conducted research has established that the ELD measurement technique is an excellent diagnostic method for HED matter. It specifically allows for direct and quantitative comparison with the results of hydrodynamic simulations, providing experimental data for verification of computer codes and underlying theoretical models. The ELD measurements will be used as a standard diagnostics in the future experiments on investigation of the HED matter induced by intense heavy ion beams, such as the HI-HEX (Heavy Ion Heating and EXpansion) EOS studies (Hoffmann et al., 2002).

Published

2002

16. Experimental investigations of multiple weak shock waves induced by intense heavy ion beams in solid matter

Author

CONSTANTIN, C., DEWALD, E., NIEMANN, C., TAHIR, N.A., SHUTOV, A., KOZYREVA, A., SCHLEGEL, T., UDREA, S., VARENTSOV, D., JACOBY, J., TAUSCHWITZ, A., FUNK, U.N., NEUNER, U., and SPILLER, P.

Abstract

The dynamics of low entropy weak shock waves induced by heavy ion beams in solid targets was investigated by means of a schlieren technique. The targets consist of a metallic absorber for the beam energy deposition followed by a plexiglass block for optical observations. Multiple waves propagating with supersonic velocities at 15 kbar pressures were observed in the plexiglass, for pressures of up to 70 kbar numerically calculated in the absorbers. Pressures in the megabar ranges are predicted for a near future beam upgrade, enabling studies of phase transition to metallic states of H, Kr, and Xe.

Published

2002

17. Time-resolved energy loss spectroscopy of energetic heavy ion beams generating a dense plasma

Author

Varentsov, D., Spiller, P., Funk, U. N., Hoffmann, D. H., Kozyreva, A., Tahir, N., Constantin, C., Dewald, E., Jacoby, J., and Neuner, U.

Published

2001

18. Electrical resistivity of high energy density matter generated by high intensity heavy ion beams

Author

Udrea, S., Shilkin, N., Varentsov, D., Tahir, N., Bock, R., Constantin, C., Dewald, E., Fortov, V., Hoffmann, D., Jacoby, J., Kulish, M., Lomonosov, I., Mintsev, V., IN, P., Nikolaev, D., and Shutov, A.

Abstract

Development of new diagnostic techniques allowed, during the past few years, for a first series of measurements on the electrical resistivity of heavy ion beam generated high energy density (HED) matter. The experimental investigations have been carried out at the HHT laboratory of the Plasma Physics Department of the Gesellschaft f?r Schwerionenforschung in Darmstadt. In this report we review the results of these experiments and discuss future experimental and theoretical work planned to be carried out within the framework of the HEDgeHOB collaboration for precise determination of the electrical resistivity of HED matter.

Published

2006

19. Present and future perspectives for high energy density physics with intense heavy ion and laser beams

Author

HOFFMANN, D.H.H., BLAZEVIC, A., NI, P., ROSMEJ, O., ROTH, M., TAHIR, N., TAUSCHWITZ, A., UDREA, S., VARENTSOV, D., WEYRICH, K., and MARON, Y.

Abstract

Volume 23, Number 1, Pages 47–53, 2005Below is the complete Reference citation for Neumayer et al. (2005).Neumayer, P., Bock, R., Borneis, S., Brambrink, E., Brand, H., Caird, J., Campbell, E.M., Gaul, E., Goette, S., Haefner, C., Hahn, T., Heuck, H.M., Hoffmann, D.H.H., Javorkova, D., Kluge, H.-J., Kuehl, Th., Kunzer, S., Merz, T., Onkels, E., Perry, M.D., Reemts, D., Roth, M., Samek, S., Schaumann, G., Schrader, F., Seelig, W., Tauschwitz, A., Thiel, R., Ursescu, D., Wiewior, P., Wittrock, U. & Zielbauer, B. (2005). Status of PHELIX laser and first experiments. Laser Part. Beams23, 87–93.

Published

2005