Your search keyword '"Louis Snydstrup"' showing total 17 results

1. Analysis of a possible 20A electron gun and collector design for the RHIC EBIS*

Author

John Ritter, Edward Beebe, J. G. Alessi, Ahovi Kponou, K. Prelec, Alexander Pikin, and Louis Snydstrup

Subjects

Physics, History, Nuclear engineering, Electron, Cathode, Computer Science Applications, Education, law.invention, law, Cathode ray, Water cooling, Atomic physics, Current density, Power density, Perveance, Electron gun

Abstract

Successful operation of the BNL EBIS with electron current up to 10 A provides optimism that EBIS operation with even higher electron current should be possible. We are now considering key aspects of the design for an EBIS operating with electron current 20 A. Several technical problems need to be resolved, including generation of a 20 A electron beam and dissipation of this electron beam power on the electron collector. Since we already have a tested concept of electron beam generation with the gun immersed in a magnetic field and subsequent purely magnetic compression of the electron beam, it makes sense to develop the new electron gun with immersed cathode but with higher perveance. To distribute the electron beam power on the surface of the electron collector more evenly, the emission current density from the cathode can be made bell-shaped with minimum close to zero on the periphery of the electron beam. With the already high requirements to the emission current density, and since such shaping of the electron beam makes these requirements even higher, perhaps the only available cathode material that can satisfy these requirements is IrCe. The problems of power dissipation on the electron collector (EC) include heat removal with cooling water and fatigue of the EC material. The first step in the EC design was electron beam transmission simulation with the goal to reduce `spikes' of power density on EC surface as much as possible. With the geometry of EC thus defined, the conditions of heat exchange for several modes of EBIS operation have been analyzed and cooling parameters, which provide adequate heat removal were found. The last step was stress analysis of several EC materials with ANSYS to find the material suitable for this application. Details of the 20 A electron gun and collector are presented.

Published

2004

2. Status of the g-2 experiment at BNL

Author

D. Kawall, V. B. Golubev, S. Kurokawa, E. P. Solodov, B. J. Hughes, G. Bunce, P. Cushman, P. von Walter, R. M. Carey, A. Stillman, P. T. Debevec, Y.Y. Lee, J. W. Jackson, G.V. Fedotovich, Louis Snydstrup, F. Toldo, A.G. Chertovskikh, Rasmus Larsen, H. Hirabayashi, J. Cullen, M. F. Hare, O. Rind, H. Deng, D. von Lintig, E. Benedict, D. Urner, David Miller, Alexei Trofimov, X. Fei, J. Benante, A. Disco, D. Winn, A. Soukas, E. Efstathiadis, F. J. M. Farley, Yannis K. Semertzidis, R. Prigl, H. N. Brown, R. McNabb, O. N. Ryskulov, Yuri Shatunov, C. Timmermans, Jinsong Ouyang, J. Geller, William Deninger, G. zu Putlitz, S. I. Redin, M. Tanaka, K. Woodle, C. Poly, E. Hazen, B. Bunker, C. Pearson, Y. Mizumachi, M. Grosse Perdekamp, H. E. Ahn, Ulrich Haeberlen, J. Pretz, K. Endo, D. Zimmerman, V. Monich, L. Jia, G. T. Danby, R. P. Shutt, J. Kindem, William Morse, T. D. Jones, A. Maskimov, L. Duong, H. Hseuh, V. P. Druzhinin, S. I. Serednyakov, F. Krienen, Wuzheng Meng, B.I. Khazin, C. Pai, Yuri F. Orlov, Michael A. Green, W. Earle, M. Mapes, A. Grossmann, V. W. Hughes, D. Warbuton, Yu Merzliakov, I. Polk, Satish Dhawan, J. Gerhaeuser, W. A. Worstell, S. Kochis, J. P. Miller, B. L. Roberts, Klaus-Peter Jungmann, Masahiko Iwasaki, J. Sandberg, S. Sedykh, S. Rankowitz, D.H Brown, D. N. Grigorev, I. Logashenko, G. S. Varner, D. W. Hertzog, A. Yamamoto, T. Tallerico, S. Giron, L. R. Sulak, and Precision Frontier

Subjects

Physics, Nuclear and High Energy Physics, Particle physics, Large Hadron Collider, Muon, Meson, Anomalous magnetic dipole moment, Physics::Instrumentation and Detectors, MUON, Atomic and Molecular Physics, and Optics, Nuclear physics, Pion, DIPOLE-MOMENT, Antimatter, Physics::Accelerator Physics, High Energy Physics::Experiment, ANOMALOUS MAGNETIC-MOMENT, Storage ring, Lepton

Abstract

The muon g-2 experiment at Brookhaven has successfully completed two exploratory runs using pion injection and direct muon injection for checkout and initial data taking. The main components of the experiment, which include the pion beam line, the superconducting storage ring and inflector magnets, the muon kicker and the lead-scintillating fiber calorimeters have been satisfactorily commissioned. First results on the anomalous magnetic moment of the positive muon from pion injection are in good agreement with previous experimental results for a(mu+) and a(mu-) from CERN and of comparable accuracy (13 ppm). Analysis of the 1998 muon injection run is in progress and expected to improve the precision to about 4 ppm. A first production run is scheduled for January 1999 with the goal of reaching the 1 ppm error level.

Published

1999

3. Test results of the g-2 superconducting solenoid magnet system

Author

L. X. Jia, R. P. Shutt, N.M. Ryskulov, Louis Snydstrup, B. L. Roberts, Y. Semertzidas, Martin A. Green, H. Hirabayashi, H. Hseuh, T. Tallerico, D. Kawall, Akira Yamamoto, G.V. Fedotovich, I. Polk, J. Cullen, Ulrich Haeberlen, Rasmus Larsen, P. von Walter, K. Endo, G. T. Danby, S.I. Redin, C. Pai, R. Prigl, M. Grosse-Perdckamp, F. Krienen, J. Geller, J. W. Jackson, Wuzheng Meng, V. W. Hughes, GZ Putlitz, Gerry Bunce, B. I. Khazin, Klaus-Peter Jungmann, K. A. Woodle, William Morse, A. Grossmann, J. Benante, and Precision Frontier

Subjects

Physics, Physics::Instrumentation and Detectors, Solenoid, Superconducting magnet, Mechanics, Cryogenics, Condensed Matter Physics, Electronic, Optical and Magnetic Materials, Dipole, Nuclear magnetic resonance, Dipole magnet, Magnet, Physics::Accelerator Physics, Electrical and Electronic Engineering, Magnetic dipole, Yoke

Abstract

The g-2 experiment dipole consists of a single 48 turn, 15.1 meter diameter outer solenoid and a pair of 24 turn inner solenoids, 13.4 meters in diameter. The inner solenoids are hooked in series and are run at a polarity that is opposite that of the outer solenoid, thus creating a dipole field in the space between the inner and outer solenoids. The dipole flux is returned by a C shaped continuous iron yoke. The superconducting solenoid coils are closely coupled to the solenoid mandrels and as such are subject to quench back. This report presents the results of various tests on the g-2 magnet system operating within its iron return yoke. These tests include quench back time constant measurements for the inner and outer solenoids and measurements of the response of the two-phase forced cooled helium cryogenic system to magnet quenches. The overall effectiveness of the g-2 magnet quench protection system was measured.

Published

1997

4. High current and high power fast kicker system conceptual design and technology overview for DeeMe experiment

Author

M. Aoki, Wuzheng Meng, Joseph Tuozzolo, C. Pai, Louis Snydstrup, J. Sandberg, N. Kawamura, P. Pile, and W. Zhang

Subjects

Inductance, Electric power transmission, Electricity generation, Nuclear magnetic resonance, Fall time, Conceptual design, Computer science, business.industry, Pulse generator, Electrical engineering, High voltage, Pulsed power, business

Abstract

A US-Japan collaboration for the high energy physics experiment DeeMe requires a multi GVA high deflection strength fast kicker system. A set of high current, high voltage and high power generators are going to drive a series of kicker magnets to deflect passing beam. Brookhaven researchers have been invited to conduct a conceptual design study for this challenging project. The basic option consists of a set of identical modulators, low impedance transmission lines, and large aperture high inductance kicker magnets. Each modulator shall be capable of driving the kicker magnet with an 8kA to 10kA pulsed current. A desired fast pulse fall time of 300 to 400 ns is the most challenging part of the design because of the high inductance magnetic load. The after pulse floor ripple tolerance is 5% or best achievable. Pulse repetition rate is 25Hz continuously. We have evaluated a wide range of pulsed power technology options and concluded that the requirement is beyond the state of the art for fast kicker technology. However, a near perfect solution is possible. We proposed several options in the conceptual design for the best achievable technical solution. In this paper, we present the technology overview, design comparisons, and the areas requiring advanced research and development effort.

Published

2013

5. The large superconducting solenoids for the g-2 muon storage ring

Author

G. T. Danby, L. X. Jia, A. Prodell, J. W. Jackson, Martin A. Green, William Morse, Akira Yamamoto, R. Shutt, C. Pai, Louis Snydstrup, I. Polk, J. R. Cullen, G. Bunce, and R. E. Meier

Subjects

Physics, Cryostat, Physics::Instrumentation and Detectors, Particle accelerator, Solenoid, Superconducting magnet, Condensed Matter Physics, Magnetic flux, Electronic, Optical and Magnetic Materials, law.invention, Magnetic field, Nuclear physics, law, Physics::Accelerator Physics, Electrical and Electronic Engineering, Magnetic dipole, Storage ring

Abstract

The g-2 muon storage ring at Brookhaven National Laboratory consists of four large superconducting solenoids. The two outer solenoids, which are 15.1 meters in diameter, share a common cryostat. The two inner solenoids, which are 13.4 meters in diameter, are in separate cryostats. The two 24 turn inner solenoids are operated at an opposite polarity from the two 24 turn outer solenoids. This generates a dipole field between the inner and outer solenoids. The flux between the solenoids is returned through a C shaped iron return yoke that also shapes the dipole field. The integrated field around the 14 meter diameter storage ring must be good to about 1 part in one million over the 90 mm dia. circular cross section where the muons are stored, averaged over the azimuth. When the four solenoids carry their 5300 A design current, the field in the 18 centimeter gap between the poles is 1.45 T. When the solenoid operates at its design current 5.5 MJ is stored between the poles. The solenoids were wound on site at Brookhaven National Laboratory. The cryostats were built around the solenoid windings which are indirectly cooled using two-phase helium. >

Published

1995

6. Cryogenics for the muon g-2 superconducting magnet system

Author

Louis J. Addessi, Robert E. Meier, Michael A. Green, Louis Snydstrup, James R. Cullen, L. X. Jia, Arnold J. Esper, Thomas N. Tallerico, and Chien-ih Pai

Subjects

Physics, Physics::Instrumentation and Detectors, Nuclear engineering, Refrigerator car, General Physics and Astronomy, chemistry.chemical_element, Solenoid, Superconducting magnet, Cryogenics, Nuclear physics, chemistry, Magnet, Water cooling, General Materials Science, Physics::Atomic Physics, Helium, Storage ring

Abstract

The g-2 muon storage ring magnet system consists of four large superconductingsolenoids that are up to 15.1 m in diameter[1,2]. In addition there is a 1.8 meter long actively shielded inflector dipole that is to guide the beam into the storage ring. The g-2 superconducting magnets will be cooled using forced two-phase helium in tubes that is provided from the J-T circuit of a 625 W refrigerator. The two-phase helium flows from the refrigerator J-T circuit through a heat exchanger in a storage dewar that acts as a phase separator and a buffer for helium returning from the magnets. The g-2 magnet cooling system consists of three parallel two-phase helium flow circuits that provide cooling to. the four large superconducting solenoids, the current interconnects between the solenoids with the 5300 A solenoid gas cooled electrical leads, and the inflector dipole with its 2850 A gas cooled electrical leads.

Published

1994

7. Improved gold ion stripping at 0.1 and10 GeV/nucleonfor the Relativistic Heavy Ion Collider

Author

Peter Thieberger, Keith Zeno, J. Benjamin, L. A. Ahrens, C.J. Gardner, J.W. Glenn, D. M. Gassner, M. Blaskiewicz, V. Zajic, N. Tsoupas, C. Carlson, W. Mac Kay, Dejan Trbojevic, Louis Snydstrup, Kevin Brown, G. Marr, D. Steski, Thomas Roser, J. G. Alessi, Joseph Brennan, Kevin Smith, and Wolfram Fischer

Subjects

Physics, Nuclear and High Energy Physics, Physics and Astronomy (miscellaneous), Ion beam, Order (ring theory), Particle accelerator, Surfaces and Interfaces, Alternating Gradient Synchrotron, Electron, law.invention, Ion, Nuclear physics, law, Physics::Accelerator Physics, Atomic physics, Nucleon, Relativistic Heavy Ion Collider

Abstract

The four electron stripping stages leading to fully stripped gold ions in the Relativistic Heavy Ion Collider (RHIC) are briefly described. The third stripper, which removes 46 electrons from the ${\mathrm{Au}}^{31+}$ ions leading to heliumlike ${\mathrm{Au}}^{77+}$, offers the greatest challenges in terms of energy loss and induced energy spread. These problems are described in detail as well as recent advances in the design and performance of this stripper. Measurements performed with several carbon and aluminum strippers show general agreement with a semiempirical model but small systematic deviations suggest that some model adjustments may be in order. The best performance is predicted and obtained with a combined carbon-aluminum foil system. Measurements showing the enhanced performance in the alternating gradient synchrotron are described. The stripper that removes the last two electrons has also been improved and the results of relevant calculations and measurements are presented.

Published

2008

8. Design and performance of the matching beamline between the BNL EBIS and an RFQ

Author

J. Brodowski, Louis Snydstrup, Alexander Pikin, Ahovi Kponou, John Ritter, Deepak Raparia, Masahiro Okamura, V. Zajic, J. G. Alessi, and Edward Beebe

Subjects

Nuclear physics, Physics, Beamline, law, Physics::Accelerator Physics, Thermal emittance, Particle accelerator, Solenoid, Space charge, Linear particle accelerator, Electrostatic lens, Beam (structure), law.invention

Abstract

A part of a new EBIS-based heavy ion preinjector, the low energy beam transport (LEBT) section between the high current EBIS and the RFQ is a challenging design, because it must serve many functions. In addition to the requirement to provide an efficient matching between the EBIS and the RFQ, this line must serve as a fast "switchyard", allowing singly charged ions from external sources to be transported into the EBIS trap region, and extracted, highly charged ions to be deflected to off-axis diagnostics (time-of-flight or emittance). The space charge of the 5-10 mA extracted heavy ion beam is a major consideration in the design, and the space charge force varies for different ion beams having Q/m from 1-0.16. The line includes electrostatic lenses, spherical and parallel-plate deflectors, magnetic solenoid, and diagnostics for measuring current, charge state distributions, emittance, and profile. A prototype of this beamline has been built, and results of tests are presented.

Published

2007

9. Uniform beam distributions at the target of the NASA Space Radiation Laboratory’s beam line

Author

P. Pile, S. Bellavia, R. Bonati, R. Prigl, I. Marneris, N. Tsoupas, Adam Rusek, Keith Zeno, S. Jao, Wuzheng Meng, C.J. Gardner, D. Phillips, W.W. MacKay, Louis Snydstrup, Kevin Brown, D. M. Gassner, L. A. Ahrens, and I-Hung Chiang

Subjects

Physics, Nuclear and High Energy Physics, Booster (rocketry), Physics and Astronomy (miscellaneous), Plane (geometry), business.industry, Surfaces and Interfaces, Alternating Gradient Synchrotron, Space radiation, Charged particle, Collimated light, Nuclear physics, Optics, Beamline, lcsh:QC770-798, Physics::Accelerator Physics, lcsh:Nuclear and particle physics. Atomic energy. Radioactivity, business, Beam (structure)

Abstract

Errors in delivering a uniformly distributed radiation dose to biological and material samples exposed to charged particle beams are a significant problem for experimenters. In this paper, we discuss data collected on the uniform beam distributions produced for NASA’s Space Radiation Laboratory (NSRL) at Brookhaven National Laboratory (BNL), using a method that was conceived theoretically and tested experimentally at BNL. This method [N. Tsoupas et al., Nucl. Sci. Eng. 126, 71 (1997)NSENAO0029-5639] of generating uniform beam distributions on a plane normal to the beam’s direction relies only on magnetically focusing the transported beam; no collimation of the beam is required or any other type of interaction of the beam with materials other than the target material. The method compares favorably with alternative methods of producing such distributions, and it can be applied to the entire energy spectrum of charged particle beams that are delivered to the NSRL’s experiments by the Booster for the Alternating Gradient Synchrotron at BNL.

Published

2007

10. RFQ AND IH accelerators for the new ebis injector at BNL

Author

Rudolf Tiede, Alwin Schempp, J. G. Alessi, Ulrich Ratzinger, D. Raparia, Louis Snydstrup, and Chuan Zhang

Subjects

Nuclear physics, Physics, Ion accelerators, law, Astrophysics::High Energy Astrophysical Phenomena, Specific mass, Physics::Accelerator Physics, Injector, Ion acceleration, Quantitative Biology::Genomics, Booster synchrotron, law.invention

Abstract

The new EBIS preinjector at BNL will accelerate ions from the EBIS source with specific mass to charge ratio of up to 6.25, from 17 keV/u to 2000 keV/u to inject into the Booster synchrotron, expanding experimental possibilities for RHIC and NASA experiments. The properties of the RFQ and IH accelerators and the status of the project will be discussed.

Published

2007

11. High performance EBIS for RHIC

Author

Ahovi Kponou, O. Gould, R. Lockey, Edward Beebe, D. Raparia, Alexander Pikin, John Ritter, J. G. Alessi, and Louis Snydstrup

Subjects

Physics, Test bench, Particle accelerator, Ion source, Synchrotron, Linear particle accelerator, Ion, law.invention, Nuclear physics, law, Physics::Accelerator Physics, Nuclear Experiment, Relativistic Heavy Ion Collider, Beam (structure)

Abstract

An electron beam ion source (EBIS), capable of producing high charge states and high beam currents of any heavy ion species in short pulses, is ideally suited for injection into a synchrotron. An EBIS-based, high current, heavy ion preinjector is now being built at Brookhaven to provide increased capabilities for the Relativistic Heavy Ion Collider (RHIC), and the NASA Space Radiation Laboratory (NSRL). Benefits of the new preinjector include the ability to produce ions of any species, fast switching between species to serve the simultaneous needs of multiple programs, and lower operating and maintenance costs. A state-of-the-art EBIS, operating with an electron beam current of up to 10 A, and producing multi-milliamperes of high charge state heavy ions, has been developed at Brookhaven, and has been operating very successfully on a test bench for several years. The present performance of this high- current EBIS is presented, along with details of the design of the scaled-up EBIS for RHIC, and the status of its construction. Other aspects of the project, including design and construction of the heavy ion RFQ, Linac, and matching beamlines, are also mentioned.

Published

2007

12. Publisher's Note: Erratum: Estimates for secondary electron emission and desorption yields in grazing collisions of gold ions with beam pipes in the BNL Relativistic Heavy Ion Collider: Proposed mitigation [Phys. Rev. ST Accel. Beams7, 093201 (2004)] [Phys. Rev. ST Accel. Beams7, 119901 (2004)]

Author

Louis Snydstrup, Wolfram Fischer, Vadim Ptitsyn, Peter Thieberger, Dejan Trbojevic, Hsiao-Chaun Hseuh, and S.Y. Zhang

Subjects

Physics, Nuclear physics, Nuclear and High Energy Physics, Physics and Astronomy (miscellaneous), Secondary emission, Desorption, Surfaces and Interfaces, Atomic physics, Relativistic Heavy Ion Collider, Beam (structure), Ion

Published

2004

13. Erratum: Estimates for secondary electron emission and desorption yields in grazing collisions of gold ions with beam pipes in the BNL Relativistic Heavy Ion Collider: Proposed mitigation [Phys. Rev. ST Accel. Beams 7, 093201 (2004)]

Author

Louis Snydstrup, S.Y. Zhang, Hsiao-Chaun Hseuh, Peter Thieberger, Dejan Trbojevic, Vadim Ptitsyn, and Wolfram Fischer

Subjects

Nuclear physics, Physics, Nuclear and High Energy Physics, Physics and Astronomy (miscellaneous), Desorption, Secondary emission, lcsh:QC770-798, lcsh:Nuclear and particle physics. Atomic energy. Radioactivity, Surfaces and Interfaces, Atomic physics, Relativistic Heavy Ion Collider, Beam (structure), Ion

Published

2004

14. Resonant Extraction Parameters for the AGS Booster

Author

Joseph Glenn, I. Marneris, M. Mapes, Kevin Brown, Louis Snydstrup, J. Cullen, N. Tsoupas, and W. van Asselt

Subjects

Nuclear physics, Physics, Booster (rocketry), Beamline, Ion accelerators, law, Magnetic separation, Physics::Accelerator Physics, Particle accelerator, Injector, Time structure, Accelerators and Storage Rings, law.invention

Abstract

Brookhaven's AGS Booster is the injector for the AGS. It is being modified to send resonant extracted heavy ions to a new beam line, the Booster Applications Facility (BAF). The design of the resonant extraction system for BAF was described previously. This note will give a more detailed description of the system and describe the predicted resonant beam time structure. We will describe tune space manipulations necessary to extract the resonant beam at the maximum Booster rigidity, schemes for performing resonant extraction, and describe the modifications required to perform bunched beam extraction to the BAF facility.

Published

2001

15. BNL ELECTRON BEAM TEST STAND

Author

J. G. Alessi, Edward Beebe, Ahovi Kponou, K. Prelec, Alexander Pikin, and Louis Snydstrup

Subjects

Nuclear physics, Materials science, law, Cathode ray, Particle accelerator, law.invention

Published

1997

16. An Ultra-Precise Storage Ring for the Muon g — 2 Measurement

Author

B. L. Roberts, D. Loomba, K. Woodle, D.H Brown, H. Venkataramania, A. Yamamoto, B. Kerosky, M. May, B. DeVito, Satish Dhawan, H. Hirabayashi, J. T. Reidy, V. W. Hughes, I. Polk, F. Krienen, A. Soukas, K. Becker, Ya. M. Shatunov, T. Sato, W. Lysenko, G. T. Danby, A. Pendzick, H. Mundinger, P. Cushman, M. S. Lubell, L. R. Sulak, J. Bailey, C. Heisey, D. Magaud, E. Hazen, F. J. M. Farley, A. Prodell, T. DeWinter, L. M. Barkov, C. Pai, G. zu Putlitz, B. Chertok, W. A. Worstell, Toichiro Kinoshita, Yuri F. Orlov, E. A. Kuraev, H. N. Brown, S. Kurokawa, A. Disco, D. Stassinopoulos, J. W. Jackson, E. Mclntyre, L. Posnlck, Louis Snydstrup, G. Cottingham, B. I. Khazin, G. Bunce, Klaus-Peter Jungmann, V. Meng, J. Cullen, D. Winn, K. Nishiyama, H. E. Ahn, K. Endo, K. Ishida, R. P. Shutt, J. Mills, K. Nagamine, and J. P. Miller

Subjects

Physics, Nuclear physics, Pole piece, Electromagnet, Anomalous magnetic dipole moment, law, Magnet, Vacuum chamber, Superconducting magnet, Storage ring, law.invention, Magnetic field

Abstract

An ultra precise 3 GeV/c storage ring with a 14.5 kG super-ferric magnet is under construction at the Brookhaven AGS for the measurement of the muon anomalous magnetic moment to 0.35 PPM accuracy. This requires a magnetic field which is constant to ≈ 1 PPM and is known sufficiently well that the magnetic field integral averaged over the muon orbits can be calculated to 0.1 PPM. First the magnetic field will be statically shimmed by various techniques. Pole face winding will be used for final small static and dynamic corrections. Very elaborate NMR field monitoring techniques are required. A “movable trolley” located inside the vacuum chamber and the electrostatic focusing quadrupoles will measure the field throughout the muon storage volume. The trolley “siding” is 180˚ from the injection point where no electric quadrupoles are located. Injection can be interrupted so the trolley can circle the ring. Also ≈ 200 NMR probes located outside the vacuum chamber monitor the field during physics running and control the pole face windings. The very large (≈ 15 m diameter) superconducting coils (SC) are designed. Test winding will soon commence. Orders for the magnet steel can now be placed. R and D on various pulsed and SC dc injection methods is ongoing.

Published

1990

17. Commissioning results of slow extraction of heavy ions from the AGS Booster

Author

A. McNerney, Y. Kotlyar, D. Gassner, James Jamilkowski, B. VanKuik, Nicholas Kling, S. Bellavia, D. DuMont, Michael Mapes, S. Zahariou-Cohen, K. A. Brown, Jon Hock, L. A. Ahrens, L. Hoff, Lee Hammons, J.W. Glenn, Travis Shrey, Louis Snydstrup, N. Tsoupas, R. Lockey, B. Brelsford, G. Marr, Seth Nemesure, Adam Rusek, S. Binello, D. Phillips, W. Eng, E. Hutchinson, A. Meyer, I. Marneris, C. Naylor, A. Krishock, Keith Zeno, C.J. Gardner, J. Ryan, and J. Morris

Subjects

Physics, Nuclear physics, Booster (rocketry), Beamline, law, Nuclear engineering, Space program, Particle accelerator, Time structure, Space radiation, law.invention, Ion

Abstract

Brookhaven's AGS Booster has been modified to deliver slow extracted beam to a new beam line, the NASA Space Radiation Laboratory (NSRL). This facility was constructed in collaboration with NASA for the purpose of performing radiation effect studies for the NASA space program. The design of the resonant extraction system has been described. A more detailed description, which includes predictions of the slow extracted beam time structure has been described. In this report we present results of the system commissioning and performance.