Your search keyword '"M. Kireeff Covo"' showing total 13 results

1. The 88-Inch Cyclotron: A one-stop facility for electronics radiation and detector testing

Author

Stephen B. Cronin, D. S. Todd, Adam Bushmaker, L. W. Phair, J. Y. Benitez, L. A. Bernstein, E. F. Matthews, T. A. Laplace, K. P. Harrig, T. Perry, Vanessa Oklejas, B.F. Ninemire, Michael B. Johnson, Alan R. Hopkins, J. A. Brown, D. L. Bleuel, Tim Loew, R.A. Albright, James E. Bevins, Don Walker, M. Harasty, A. Hodgkinson, Jihan Chen, M. Kireeff Covo, D. Z. Xie, and Bethany L. Goldblum

Subjects

Nuclear engineering, Cyclotron, 02 engineering and technology, 01 natural sciences, law.invention, Nuclear physics, law, 0103 physical sciences, Microelectronics, Neutron, Electronics, Electrical and Electronic Engineering, Nuclear Experiment, 010306 general physics, Instrumentation, Radiation hardening, Physics, business.industry, Applied Mathematics, Detector, Particle accelerator, Neutron radiation, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Physics::Accelerator Physics, 0210 nano-technology, business

Abstract

In outer space down to the altitudes routinely flown by larger aircrafts, radiation can pose serious issues for microelectronics circuits. The 88-Inch Cyclotron at Lawrence Berkeley National Laboratory is a sector-focused cyclotron and home of the Berkeley Accelerator Space Effects Facility, where the effects of energetic particles on sensitive microelectronics are studied with the goal of designing electronic systems for the space community. This paper describes the flexibility of the facility and its capabilities for testing the bombardment of electronics by heavy ions, light ions, and neutrons. Experimental capabilities for the generation of neutron beams from deuteron breakups and radiation testing of carbon nanotube field effect transistor will be discussed.

Published

2018

2. First Direct Measurements of Superheavy-Element Mass Numbers

Author

L. W. Phair, G. K. Pang, R. M. Clark, J. M. Gates, M. J. Mogannam, A. O. Macchiavelli, C. Morse, Guy Savard, M. A. Stoyer, N. E. Esker, J. C. Batchelder, J. L. Pore, R. Orford, H. L. Crawford, K. K. Hubbard, J. T. Kwarsick, Kenneth E. Gregorich, I. T. Kolaja, A. M. Hurst, P. Fallon, M. Kireeff Covo, and D. L. Bleuel

Subjects

Mass number, Physics, General Physics, 010308 nuclear & particles physics, Cyclotron, General Physics and Astronomy, Superheavy Elements, 01 natural sciences, Mathematical Sciences, law.invention, Nuclear physics, Engineering, law, 0103 physical sciences, Physical Sciences, Element (category theory), 010306 general physics, National laboratory, Event (probability theory)

Abstract

© 2018 American Physical Society. An experiment was performed at Lawrence Berkeley National Laboratory's 88-in. Cyclotron to determine the mass number of a superheavy element. The measurement resulted in the observation of two α-decay chains, produced via the Am243(Ca48,xn)291-xMc reaction, that were separated by mass-to-charge ratio (A/q) and identified by the combined BGS+FIONA apparatus. One event occurred at A/q=284 and was assigned to Nh284 (Z=113), the α-decay daughter of Mc288 (Z=115), while the second occurred at A/q=288 and was assigned to Mc288. This experiment represents the first direct measurements of the mass numbers of superheavy elements, confirming previous (indirect) mass-number assignments.

Published

2018

3. Self-consistent simulations of heavy-ion beams interacting with electron-clouds

Author

Aharon Friedman, J.-L. Vay, David P. Grote, Peter Stoltz, Peter A. Seidl, Ronald H. Cohen, Seth Veitzer, A.W. Molvik, John P. Verboncoeur, Miguel A. Furman, and M. Kireeff Covo

Subjects

Physics, Nuclear and High Energy Physics, Large Hadron Collider, Particle accelerator, Electron, Plasma, law.invention, Nuclear physics, Atomic orbital, law, Ionization, Particle-in-cell, Instrumentation, Beam (structure)

Abstract

Electron-clouds and rising desorbed gas pressure limit the performance of many existing accelerators and, potentially, that of future accelerators including heavy-ion warm-dense matter and fusion drivers. For the latter, self-consistent simulation of the interaction of the heavy-ion beam(s) with the electron-cloud is necessary. To this end, we have merged the two codes WARP (HIF accelerator code) and POSINST (high-energy e-cloud build-up code), and added modules for neutral gas molecule generation, gas ionization, and electron tracking algorithms in magnetic fields with large time steps. The new tool is being benchmarked against the High-Current Experiment (HCX) and good agreement has been achieved. The simulations have also aided diagnostic interpretation and have identified unanticipated physical processes. We present the ''roadmap'' describing the different modules and their interconnections, along with detailed comparisons with HCX experimental results, as well as a preliminary application to the modeling of electron clouds in the Large Hadron Collider.

Published

2007

4. Quantitative electron and gas cloud experiments

Author

F.M. Bieniosek, C. Leister, J.-L. Vay, Ronald H. Cohen, M. Kireeff Covo, D. Baca, A.W. Molvik, Peter A. Seidl, W.M. Sharp, and Aharon Friedman

Subjects

Physics, Nuclear and High Energy Physics, Electron density, Proton, Particle accelerator, Electron, law.invention, law, Ionization, Quadrupole, Physics::Accelerator Physics, Atomic physics, Quadrupole magnet, Instrumentation, Beam (structure)

Abstract

Electrons can accumulate in and degrade the quality of positively charged beams. This is a well-known problem in proton storage rings. Heavy-ion rings are more frequently limited by gas pressure-rise effects. Both effects may limit how closely the beam radius can approach the beam-tube radius in a heavy-ion linac. We study beams of 1 MeV K + with currents of up to 180 mA in the High-Current Experiment (HCX), and compare our work with simulations. The theory and simulation results are discussed in a companion papers. We have developed the first diagnostics that quantitatively measure the accumulation of electrons in a beam [M. Kireeff Covo, A. Molvik, A. Friedman, J.-L. Vay, P. Seidl, G. Logan, D. Baca, J.L. Vujic, Phys. Rev. Lett. 97 (2006) 054801; M. Kireeff Covo, et al., Nucl. Instr. and Meth. A, 2007, in press, doi:10.1016/j.nima.2007.02.045.]. This will enable the particle balance to be measured for each source of electrons in a linac: ionization of gas, emission from walls surrounding the beam, and emission from an end wall coupled with electron drifts upstream through quadrupole magnets, and electron-trapping efficiencies can be determined. Experiments where the heavy-ion beam is transported with solenoid magnetic fields, rather than with quadrupole magnetic or electrostatic fields, are being initiated. We discuss plans for experiments using electrode sets (in the middle and at the ends of magnets) to either expel or to trap electrons within the magnets. We observe oscillations of the electron density and position in the last quadrupole magnet when we flood the beam with electrons from an end wall. These oscillations, near 6 MHz, are observed to grow from the center of the magnet while drifting upstream against the beam, in good agreement with simulations.

Published

2007

5. US heavy ion beam research for high energy density physics applications and fusion

Author

R.J. Briggs, Debra Callahan, W.L. Waldron, Max Tabak, Enrique Henestroza, David P. Grote, Christine M. Celata, Edward A. Startsev, Erik P. Gilson, J.-L. Vay, G.A. Westenskow, W.W. Lee, Simon S. Yu, M. Kireeff Covo, Prabir K. Roy, Larry R. Grisham, S.M. Lund, Dale Welch, Hong Qin, Craig L. Olson, J.W. Kwan, F.M. Bieniosek, Carsten Thoma, Wayne R. Meier, Ronald C. Davidson, Jonathan Wurtele, B.G. Logan, Peter A. Seidl, Ronald H. Cohen, W.M. Sharp, Matthaeus Leitner, P. C. Efthimion, A.W. Molvik, Edward P. Lee, Igor Kaganovich, J.J. Barnard, D. V. Rose, Shmuel Eylon, Aharon Friedman, Joshua Coleman, C.S. Debonnel, Adam B Sefkow, and Gregory Penn

Subjects

High Energy Density Matter, Ion beam, Chemistry, Nuclear engineering, General Physics and Astronomy, Particle accelerator, Warm dense matter, Fusion power, Linear particle accelerator, Ion, law.invention, Nuclear physics, Physics::Plasma Physics, law, Inertial confinement fusion

Abstract

Key scientific results from recent experiments, modeling tools, and heavy ion accelerator research are summarized that explore ways to investigate the properties of high energy density matter in heavy-ion-driven targets, in particular, strongly-coupled plasmas at 0.01 to 0.1 times solid density for studies of warm dense matter, which is a frontier area in high energy density physics. Pursuit of these near-term objectives has resulted in many innovations that will ultimately benefit heavy ion inertial fusion energy. These include: neutralized ion beam compression and focusing, which hold the promise of greatly improving the stage between the accelerator and the target chamber in a fusion power plant; and the Pulse Line Ion Accelerator (PLIA), which may lead to compact, low-cost modular linac drivers.

Published

2006

6. Experimental studies of electrons in a heavy-ion beam

Author

Aharon Friedman, S.M. Lund, M. Kireeff Covo, Ronald H. Cohen, F.M. Bieniosek, L. Prost, Peter A. Seidl, A. Faltens, and A.W. Molvik

Subjects

Physics, Nuclear and High Energy Physics, Electron, Ion, law.invention, Pressure measurement, Atomic orbital, law, Desorption, Physics::Accelerator Physics, Atomic physics, Quadrupole magnet, Instrumentation, Astrophysics::Galaxy Astrophysics, Electron ionization, Beam (structure)

Abstract

We have measured electron and gas emission from 1 MeV K + impact on surfaces near grazing incidence on the High-Current Experiment (HCX) at LBNL. Electron emission coefficients reach values of 130, whereas gas desorption coefficients are near 10 4 . Mitigation techniques are being studied: a bead-blasted rough surface reduces electron emission by a factor of 10 and gas desorption by a factor of 2. Diagnostics are installed on HCX, between and within quadrupole magnets, to measure the beam halo loss, net charge and expelled ions, from which we infer gas density, electron trapping, and the effects of mitigation techniques. Here we discuss a new diagnostic technique that measures gas pressure and electron ionization rates within quadrupole magnets during the beam transit.

Published

2005

7. Experimental study of the transport limits of intense heavy ion beams in the HCX

Author

Ronald H. Cohen, A.W. Molvik, S.M. Lund, Christine M. Celata, F.M. Bieniosek, Irving Haber, L. Prost, Peter A. Seidl, M. Kireeff Covo, W.L. Waldron, Aharon Friedman, and A. Faltens

Subjects

Physics, Nuclear and High Energy Physics, Beam diameter, Ion beam, Particle accelerator, Fusion power, Linear particle accelerator, law.invention, Nuclear physics, law, Fermilab, Atomic physics, Instrumentation, Beam (structure), Fermi Gamma-ray Space Telescope

Abstract

W.I-07 EXPERIMENTAL STUDY OF THE TRANSPORT LIMITS OF INTENSE HEAVY ION BEAMS IN THE HCX 1 L. R. Prost (FNAL), F. M. Bieniosek (LBNL), C.M. Celata (LBNL), A. Faltens (LBNL), P. A. Seidl (LBNL), W. L. Waldron (LBNL) R. Cohen (LLNL), A. Friedman (LLNL), M. Kireeff Covo (LLNL), S.M. Lund (LLNL), A.W. Molvik (LLNL) I. Haber (UM) FNAL: Fermi National Accelerator Laboratory, Batavia, IL, 60510 USA LBNL: Lawrence Berkeley National Laboratory, Berkeley, CA, 94720-8201 LLNL: Lawrence Livermore National Laboratory, Livermore, CA 94550 USA UM: University of Maryland, College Park, MD 20742-3511 Corresponding author: Lionel Prost FERMILAB P.O. Box 500 – MS 306 Batavia, IL, 60510 USA Tel: Fax: E-mail: lprost@fnal.gov Abstract The High Current Experiment (HCX) at Lawrence Berkeley National Laboratory is part of the US program to explore heavy-ion beam transport at a scale representative of the low-energy end of an induction linac driver for fusion energy production. The primary mission of this experiment is to investigate aperture fill factors acceptable for the transport of space-charge-dominated heavy-ion beams at high space-charge intensity (line charge density up to ~ 0.2 µC/m) over long pulse durations (4 µs) in alternating gradient focusing lattices of electrostatic or magnetic quadrupoles. The experiment also contributes to the practical baseline knowledge of intense beam manipulations necessary for the design, construction and operation of a heavy ion driver for inertial fusion. This experiment is testing transport issues resulting from nonlinear space-charge effects and collective modes, beam centroid alignment and beam steering, matching, image charges, halo, electron cloud effects, and longitudinal bunch control. We first present the results for a coasting 1 MeV K + ion beam transported through the first ten electrostatic transport quadrupoles, measured with optical beam-imaging and double-slit phase-space diagnostics. This includes studies at two different radial fill factors (60% and 80%), for which the beam transverse distribution was characterized in detail. Additionally, beam This work performed under the auspices of the U.S Department of Energy by University of California, Lawrence Livermore and Lawrence Berkeley National Laboratories under contracts No. W-7405-Eng-48 and DE-AC03-76SF00098.

Published

2005

8. Overview of US heavy-ion fusion progress and plans

Author

Christine M. Celata, Ronald C. Davidson, Simon C. M. Yu, Igor Kaganovich, Edward A. Startsev, P. C. Efthimion, A.W. Molvik, Ronald H. Cohen, M. Kireeff Covo, Edward P. Lee, L. Prost, J.J. Barnard, Patrick G. O'Shea, Irving Haber, Matthaeus Leitner, Dale Welch, Aharon Friedman, R. A. Kishek, Debra Callahan, W.L. Waldron, Larry R. Grisham, F.M. Bieniosek, Enrique Henestroza, Prabir K. Roy, Hong Qin, Grant Logan, David P. Grote, Craig L. Olson, Peter A. Seidl, Erik P. Gilson, Wayne R. Meier, Shmuel Eylon, J.-L. Vay, D. V. Rose, S.M. Lund, and J.W. Kwan

Subjects

Physics, Nuclear and High Energy Physics, Particle accelerator, Plasma, Fusion power, Linear particle accelerator, law.invention, Nuclear physics, law, Quadrupole, Physics::Accelerator Physics, Thermal emittance, Beam emittance, Instrumentation, Beam (structure)

Abstract

Significant experimental and theoretical progress has been made in the US heavy-ion fusion program on high-current sources, injectors, transport, final focusing, chambers and targets for high-energy density physics (HEDP) and inertial fusion energy (IFE) driven by induction linac accelerators. One focus of present research is the beam physics associated with quadrupole focusing of intense, space–charge dominated heavy-ion beams, including gas and electron cloud effects at high currents, and the study of long-distance-propagation effects such as emittance growth due to field errors in scaled experiments. A second area of emphasis in present research is the introduction of background plasma to neutralize the space charge of intense heavy-ion beams and assist in focusing the beams to a small spot size. In the near future, research will continue in the above areas, and a new area of emphasis will be to explore the physics of neutralized beam compression and focusing to high intensities required to heat targets to high-energy density conditions as well as for inertial fusion energy.

Published

2005

9. Overview of US heavy ion fusion research

Author

Craig L. Olson, Patrick G. O'Shea, Ronald H. Cohen, R. A. Kishek, P. C. Efthimion, Dale Welch, Edward P. Lee, L. Prost, Alex Friedman, Irving Haber, L. R. Grisham, M. Kireeff Covo, David P. Grote, Matthaeus Leitner, Edward A. Startsev, Shmuel Eylon, Simon S. Yu, Wayne R. Meier, F.M. Bieniosek, J.J. Barnard, A.W. Molvik, Enrique Henestroza, Prabir K. Roy, B.G. Logan, Erik P. Gilson, Peter A. Seidl, Debra Callahan, W.L. Waldron, D. V. Rose, Christine M. Celata, J.-L. Vay, Hong Qin, Igor Kaganovich, S.M. Lund, J.W. Kwan, and Ronald C. Davidson

Subjects

Physics, Nuclear and High Energy Physics, Particle accelerator, Plasma, Fusion power, Condensed Matter Physics, Linear particle accelerator, Environmental Energy Technologies, law.invention, Nuclear physics, law, Quadrupole, Physics::Accelerator Physics, Thermal emittance, Inertial confinement fusion, Beam (structure)

Abstract

Significant experimental and theoretical progress has been made in the U.S. heavy ion fusion program on high-current sources, injectors, transport, final focusing, chambers and targets for high energy density physics (HEDP) and inertial fusion energy (IFE) driven by induction linac accelerators. One focus of present research is the beam physics associated with quadrupole focusing of intense, space-charge dominated heavy-ion beams, including gas and electron cloud effects at high currents, and the study of long-distance-propagation effects such as emittance growth due to field errors in scaled experiments. A second area of emphasis in present research is the introduction of background plasma to neutralize the space charge of intense heavy ion beams and assist in focusing the beams to a small spot size. In the near future, research will continue in the above areas, and a new area of emphasis will be to explore the physics of neutralized beam compression and focusing to high intensities required to heat targets to high energy density conditions as well as for inertial fusion energy.

Published

2005

10. TU-FG-BRB-09: Thermoacoustic Range Verification with Perfect Co-Registered Overlay of Bragg Peak onto Ultrasound Image

Author

M. Kireeff Covo, S. Small, R.A. Albright, S Patch, C R Siero, K S Campbell, Alexander P. Donoghue, L. W. Phair, Michael B. Johnson, P Bloemhard, A Jackson, Y Qadadha, B.F. Ninemire, and T. Gimpel

Subjects

Range (particle radiation), Particle therapy, Materials science, business.industry, medicine.medical_treatment, Cyclotron, Thermoacoustics, Bragg peak, General Medicine, Imaging phantom, law.invention, Chopper, Optics, Transducer, law, medicine, business

Abstract

Purpose: The potential of particle therapy has not yet been fully realized due to inaccuracies in range verification. The purpose of this work was to correlate the Bragg peak location with target structure, by overlaying thermoacoustic localization of the Bragg peak onto an ultrasound image. Methods: Pulsed delivery of 50 MeV protons was accomplished by a fast chopper installed between the ion source and the inflector of the 88″ cyclotron at Lawrence Berkeley National Lab. 2 Gy were delivered in 2 µs by a beam with peak current of 2 µA. Thermoacoustic emissions were detected by a cardiac array and Verasonics V1 ultrasound system, which also generated a grayscale ultrasound image. 1024 thermoacoustic pulses were averaged before filtering and one-way beamforming focused signal onto the Bragg peak location with perfect co-registration to the ultrasound images. Data was collected in a room temperature water bath and gelatin phantom with a cavity designed to mimic the intestine, in which gas pockets can displace the Bragg peak. Experiments were performed with the cavity both empty and filled with olive oil. Results: In the waterbath overlays of the Bragg peak agreed with Monte Carlo simulations to within 800±170 µm. Agreement within 1.3 ± 0.2 mm was achieved in the gelatin phantom, although relative stopping powers were estimated only to first order from CT scans. Protoacoustic signals were detected after travel from the Bragg peak through 29 mm and 65 mm of phantom material when the cavity was empty and full of olive oil, respectively. Conclusion: Protoacoustic range verification is feasible with a commercial clinical ultrasound array, but at doses exceeding the clinical realm. Further optimization of both transducer array and injection line chopper is required to enable range verification within a 2 Gy dose limit, which would enable online adaptive treatment. This work was supported in part by a UWM Intramural Instrumentation Grant and by the Director, Office of Science, Office of Nuclear Physics, of the U.S. Department of Energy under Contract No. DE-AC02-05CH11231. YMQ was supported by a UWM-OUR summer fellowship.

Published

2016

11. Critical issues for high-brightness heavy-ion beams- prioritized

Author

Hong Qin, Alex Friedman, J-L. Vay, Ronald H. Cohen, M. Kireeff Covo, Edward P. Lee, S.M. Lund, Igor Kaganovich, J.W. Kwan, David P. Grote, Ronald C. Davidson, Simon S. Yu, Irving Haber, L. R. Grisham, P.A. Seidl, B.G. Logan, A. Faltens, A.W. Molvik, and W.M. Sharp

Subjects

Physics, Brightness, law, Limit (music), Thermal emittance, Heavy ion, Particle accelerator, Nanotechnology, Current (fluid), Beam (structure), Reliability engineering, law.invention, Term (time)

Abstract

This study group was initiated to consider whether there were any ''show-stopper'' issues with accelerators for heavy-ion warm-dense matter (WDM) and heavy-ion inertial fusion energy (HIF), and to prioritize them. Showstopper issues would appear as limits to beam current; that is, the beam would be well-behaved below the current limit, and significantly degraded in current or emittance if the current limit were exceeded at some region of an accelerator. We identified 14 issues: 1-6 could be addressed in the near term, 7-10 are potentially attractive solutions to performance and cost issues but are not yet fully characterized, 11-12 involve multibeam effects that cannot be more than partially studied in near-term facilities, and 13-14 involve new issues that are present in some novel driver concepts. Comparing the issues with the new experimental, simulation, and theoretical tools that we have developed, it is apparent that our new capabilities provide an opportunity to re-examine and significantly increase our understanding of the number one issue--halo growth and mitigation.

Published

2007

12. Heavy-ion-induced electronic desorption of gas from metals

Author

Oleg B. Malyshev, E. Mahner, A.W. Molvik, E. Hedlund, F.M. Bieniosek, M. Kireeff Covo, M. Bender, Lars Westerberg, J.W. Kwan, L. Prost, H. Kollmus, G.A. Westenskow, M. C. Bellachioma, A. Krämer, and Peter A. Seidl

Subjects

Physics, Ion beam, Orders of magnitude (temperature), General Physics and Astronomy, Particle accelerator, Accelerators and Storage Rings, law.invention, Ion, Physics::Plasma Physics, Sputtering, law, Desorption, Physics::Accelerator Physics, Vacuum chamber, Atomic physics, Nuclear Experiment, Beam (structure)

Abstract

During heavy-ion operation in several particle accelerators worldwide, dynamic pressure rises of orders of magnitude were triggered by lost beam ions that bombarded the vacuum chamber walls. This ion-induced molecular desorption, observed at CERN, GSI, and BNL, can seriously limit the ion beam lifetime and intensity of the accelerator. From dedicated test stand experiments we have discovered that heavy-ion-induced gas desorption scales with the electronic energy loss (dE{sub e}/dx) of the ions slowing down in matter; but it varies only little with the ion impact angle, unlike electronic sputtering.

Published

2006

13. Comparison of electron cloud simulation and experiments in the high-current experiment

Author

J-L. Vay, John P. Verboncoeur, Peter Stoltz, Alex Friedman, Ronald H. Cohen, P.A. Seidl, M. Kireeff Covo, F.M. Bieniosek, Seth Veitzer, S.M. Lund, and A.W. Molvik

Subjects

Physics, Two-stream instability, Ion beam, law, Magnet, Cyclotron, Particle accelerator, Electron, Atomic physics, Quadrupole magnet, Ion, law.invention

Abstract

A set of experiments has been performed on the High-Current Experiment (HCX) facility at LBNL, in which the ion beam is allowed to collide with an end plate and thereby induce a copious supply of desorbed electrons. Through the use of combinations of biased and grounded electrodes positioned in between and downstream of the quadrupole magnets, the flow of electrons upstream into the magnets can be turned on or off. Properties of the resultant ion beam are measured under each condition. The experiment is modeled via a full three-dimensional, two species (electron and ion) particle simulation, as well as via reduced simulations (ions with appropriately chosen model electron cloud distributions, and a high-resolution simulation of the region adjacent to the end plate). The three-dimensional simulations are the first of their kind and the first to make use of a timestep-acceleration scheme that allows the electrons to be advanced with a timestep that is not small compared to the highest electron cyclotron period. The simulations reproduce qualitative aspects of the experiments, illustrate some unanticipated physical effects, and serve as an important demonstration of a developing simulation capability.

Published

2004