Your search keyword '"J. Bessuille"' showing total 19 results

1. Compact x-ray source based on burst-mode inverse Compton scattering at 100 kHz

Author

W. S. Graves, J. Bessuille, P. Brown, S. Carbajo, V. Dolgashev, K.-H. Hong, E. Ihloff, B. Khaykovich, H. Lin, K. Murari, E. A. Nanni, G. Resta, S. Tantawi, L. E. Zapata, F. X. Kärtner, and D. E. Moncton

Subjects

Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

A design for a compact x-ray light source (CXLS) with flux and brilliance orders of magnitude beyond existing laboratory scale sources is presented. The source is based on inverse Compton scattering of a high brightness electron bunch on a picosecond laser pulse. The accelerator is a novel high-efficiency standing-wave linac and rf photoinjector powered by a single ultrastable rf transmitter at X-band rf frequency. The high efficiency permits operation at repetition rates up to 1 kHz, which is further boosted to 100 kHz by operating with trains of 100 bunches of 100 pC charge, each separated by 5 ns. The entire accelerator is approximately 1 meter long and produces hard x rays tunable over a wide range of photon energies. The colliding laser is a Yb∶YAG solid-state amplifier producing 1030 nm, 100 mJ pulses at the same 1 kHz repetition rate as the accelerator. The laser pulse is frequency-doubled and stored for many passes in a ringdown cavity to match the linac pulse structure. At a photon energy of 12.4 keV, the predicted x-ray flux is 5×10^{11} photons/second in a 5% bandwidth and the brilliance is 2×10^{12} photons/(sec mm^{2} mrad^{2} 0.1%) in pulses with rms pulse length of 490 fs. The nominal electron beam parameters are 18 MeV kinetic energy, 10 microamp average current, 0.5 microsecond macropulse length, resulting in average electron beam power of 180 W. Optimization of the x-ray output is presented along with design of the accelerator, laser, and x-ray optic components that are specific to the particular characteristics of the Compton scattered x-ray pulses.

Published

2014

2. General Failure Modes and Effects Analysis for Accelerator and Detector Magnet Design at JLab

Author

Probir K. Ghoshal, Ruben J. Fair, Renuka Rajput-Ghoshal, Sandesh Gopinath, J. Kelsey, D. Kashy, Ernie Ihloff, K. S. Kumar, J. Bessuille, Juliette Mammie, Chandan Ghosh, and S. Rahman

Subjects

Process (engineering), business.industry, Condensed Matter Physics, 01 natural sciences, Outcome (game theory), Electronic, Optical and Magnetic Materials, Reliability engineering, Identification (information), 0103 physical sciences, Design process, Process control, Electrical and Electronic Engineering, 010306 general physics, business, Engineering design process, Failure mode and effects analysis, Risk management

Abstract

The aim of this article is to develop a risk management procedure, which could be applied to the magnet design process, for both superconducting and normal magnets at the Jefferson Laboratory (JLab). This procedure allowed us to identify the key risks at each of the critical phases of design and propose procedures, tests, and checks to mitigate each risk. In this article, we present a qualitative and quantitative risk management procedure commonly referred to a “failure modes and effects analysis.” As part of this procedure, we calculated a risk priority number (RPN) for each activity of the process, identified the most critical activities and proposed mitigation activities, which in turn resulted in a revised RPN. Another benefit of this procedure was the identification of appropriate “control and hold” points within the design process, which allowed one to review and approve a particular outcome before proceeding to the next sequential activity.

Published

2020

3. Initial performance of the GlueX DIRC detector

Author

A Ali, F Barbosa, J Bessuille, E Chudakov, R Dzhygadlo, C Fanelli, J Frye, J Hardin, A Hurley, E Ihloff, G Kalicy, J Kelsey, W B Li, M Patsyuk, J Schwiening, M Shepherd, J R Stevens, T Whitlatch, M Williams, and Y Yang

Subjects

History, Physics - Instrumentation and Detectors, Physics::Instrumentation and Detectors, FOS: Physical sciences, ddc:530, High Energy Physics::Experiment, Instrumentation and Detectors (physics.ins-det), Nuclear Experiment, Computer Science Applications, Education

Abstract

The GlueX experiment at Jefferson Laboratory aims to perform quantitative tests of non-perturbative QCD by studying the spectrum of light-quark mesons and baryons. A Detector of Internally Reflected Cherenkov light (DIRC) was installed to enhance the particle identification (PID) capability of the GlueX experiment by providing clean $\pi$/K separation up to 3.7 GeV/$c$ momentum in the forward region ($\theta, Comment: International Conference on Technology and Instrumentation in Particle Physics 2021, 5 pages

Published

2022

4. Searching for New Physics with DarkLight at the ARIEL Electron-Linac

Author

E Cline, R Corliss, J C Bernauer, R Alarcon, R Baartman, S Benson, J Bessuille, D Ciarniello, A Christopher, A Colon, W Deconinck, K Dehmelt, A Deshpande, J Dilling, D H Dongwi, P Fisher, T Gautam, M Gericke, D Hasell, M Hasinoff, E Ihloff, R Johnston, R Kanungo, J Kelsey, O Kester, M Kohl, I Korover, R Laxdal, S Lee, X Li, C Ma, A Mahon, J W Martin, R Milner, M Moore, P Moran, J Nazeer, K Pachal, T Patel, T Planche, M Rathnayake, M Suresh, C Vidal, Y Wang, and S Yen

Subjects

History, Computer Science Applications, Education

Abstract

The search for a dark photon holds considerable interest in the physics community. Such a force carrier would begin to illuminate the dark sector. Many experiments have searched for such a particle, but so far it has proven elusive. In recent years the concept of a low mass dark photon has gained popularity in the physics community. Of particular recent interest is the 8Be and 4He anomaly, which could be explained by a new fifth force carrier with a mass of 17 MeV/c 2. The proposed Darklight experiment would search for this potential low mass force carrier at ARIEL in the 10-20 MeV/c 2 e+e− invariant mass range. This proceeding will focus on the experimental design and physics case of the Darklight experiment.

Published

2022

5. The GlueX DIRC Program

Author

J. Kelsey, M. Patsyuk, J. Hardin, J. Schwiening, A. Hurley, C. Schwarz, W. Li, E. Chudakov, Abbas J. Ali, F. Barbosa, Yang Yang, J. R. Stevens, C. Fanelli, M. Shepherd, R. Dzhygadlo, J. Bessuille, T. Whitlatch, Marian E. Williams, J. Frye, and G. Kalicy

Subjects

Physics, Particle physics, GlueX, Physics - Instrumentation and Detectors, Meson, 010308 nuclear & particles physics, Physics::Instrumentation and Detectors, Nuclear Theory, FOS: Physical sciences, Instrumentation and Detectors (physics.ins-det), 01 natural sciences, 030218 nuclear medicine & medical imaging, Identification system, 03 medical and health sciences, 0302 clinical medicine, Detection of internally reflected Cherenkov light, 0103 physical sciences, Physics::Accelerator Physics, High Energy Physics::Experiment, Photon beam, Nuclear Experiment (nucl-ex), Nuclear Experiment, Instrumentation, Mathematical Physics

Abstract

© 2020 IOP Publishing Ltd and Sissa Medialab. The GLUEX experiment is located in experimental Hall D at Jefferson Lab (JLab) and provides a unique capability to search for hybrid mesons in high-energy photoproduction, utilizing a ∼9 GeV linearly polarized photon beam. The initial, low-intensity phase of GLUEX was recently completed and a high-intensity phase has begun in 2020 which includes an upgraded kaon identification system, known as the DIRC (Detection of Internally Reflected Cherenkov light), utilizing components from the decommissioned BaBar DIRC. The identification of kaon final states will significantly enhance the GLUEX physics program, to aid in inferring the quark flavor content of conventional (and potentially hybrid) mesons. In these proceedings, we describe the installation of the GLUEX DIRC and the analysis of initial commissioning data.

Published

2020

6. High intensity polarized electron source

Author

C. Vidal, Evgeni Tsentalovich, J. Kelsey, J. Bessuille, R. P. Redwine, E. Ihloff, Bates Linear Accelerator Center, Massachusetts Institute of Technology. Laboratory for Nuclear Science, and Massachusetts Institute of Technology. Department of Physics

Subjects

Physics, Nuclear and High Energy Physics, Range (particle radiation), business.industry, High intensity, Electron source, law.invention, Optics, Beamline, law, Physics::Accelerator Physics, High Energy Physics::Experiment, business, Collider, National laboratory, Nuclear Experiment, Instrumentation, Beam (structure), Electron gun

Abstract

A proposed new high-luminosity electron–ion collider requires a polarized electron source of extremely high intensity. The MIT-Bates Laboratory, in collaboration with Brookhaven National Laboratory (BNL), has developed a new polarized electron gun that can be operated at currents in the mA range. This paper describes the design of the gun and beam line and also presents the results of the beam tests., DOE (Grants DE-­FG02-­94ER40818, DE-­SC0005807 and DE-­SC0008741)

Published

2019

7. Design and Operation of a Windowless Gas Target Internal to a Solenoidal Magnet for Use with a Megawatt Electron Beam

Author

P. Moran, R. Kazimi, P. H. Fisher, Jan C. Bernauer, Y. F. Wang, C. Tschalär, Kevin Jordan, M. Garçon, M. McCaughan, J. Kelsey, Ivica Friščić, E. Ihloff, G. Randall, D. Hasell, S. Frierson, Carlos Hernandez-Garcia, James Coleman, Richard G. Milner, J. Balewski, Michael Kohl, Shukui Zhang, S. Lee, J. Nazeer, D. Palumbo, C. Vogel, Joseph Grames, Ricardo Alarcon, S.V. Benson, M. Poelker, James Boyce, R. Corliss, J. Bessuille, S. Aulenbacher, A. Liyanage, C.S. Epstein, S. G. Steadman, Chris Tennant, David Douglas, R. Johnston, C. Vidal, Institut de Recherches sur les lois Fondamentales de l'Univers (IRFU), and Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay

Subjects

Nuclear and High Energy Physics, Physics - Instrumentation and Detectors, Orders of magnitude (temperature), Windowless gas target, Nuclear engineering, DarkLight, FOS: Physical sciences, [PHYS.NEXP]Physics [physics]/Nuclear Experiment [nucl-ex], 01 natural sciences, 7. Clean energy, COMSOL, Free molecular flow, 0103 physical sciences, Calibration, [PHYS.PHYS.PHYS-INS-DET]Physics [physics]/Physics [physics]/Instrumentation and Detectors [physics.ins-det], Nuclear Experiment (nucl-ex), 010306 general physics, Instrumentation, Nuclear Experiment, Physics, Solenoidal vector field, 010308 nuclear & particles physics, Laminar flow, Dark photon, Instrumentation and Detectors (physics.ins-det), Beamline, Magnet, Cathode ray

Abstract

A windowless hydrogen gas target of nominal thickness $10^{19}$ cm$^{-2}$ is an essential component of the DarkLight experiment, which is designed to utilize the megawatt electron beam at an Energy Recovery Linac (ERL). The design of such a target is challenging because the pressure drops by many orders of magnitude between the central, high-density section of the target and the surrounding beamline, resulting in laminar, transitional, and finally molecular flow regimes. The target system was assembled and operated at Jefferson Lab's Low Energy Recirculator Facility (LERF) in 2016, and subsequently underwent several revisions and calibration tests at MIT Bates in 2017. The system at dynamic equilibrium was simulated in COMSOL to provide a better understanding of its optimal operation at other working points. We have determined that a windowless gas target with sufficiently high density for DarkLight's experimental needs is feasible in an ERL environment., 11 pages, 14 figures; v2: minor improvements; v3: author list updated; v4: minor revision

Published

2019

8. The GlueX DIRC detector

Author

Mark Richard James Williams, J. R. Stevens, J. Bessuille, T. Whitlatch, J. Kelsey, J. Hardin, R. Dzhygadlo, F. Barbosa, C. Fanelli, M. R. Shepherd, J. Schwiening, E. Chudakov, M. Patsyuk, C. Schwarz, and J. Frye

Subjects

Physics, Nuclear and High Energy Physics, Particle physics, GlueX, 010308 nuclear & particles physics, Detector, 01 natural sciences, Linear particle accelerator, Particle detector, Particle identification, Upgrade, Detection of internally reflected Cherenkov light, 0103 physical sciences, 010306 general physics, Instrumentation

Abstract

The GlueX DIRC (Detection of Internally Reflected Cherenkov light) detector is being developed to upgrade the particle identification capabilities in the forward region of the GlueX experiment at Jefferson Lab. The GlueX DIRC will utilize four existing decommissioned BaBar DIRC bar boxes, which will be oriented to form a plane roughly 4 m away from the fixed target of the experiment. A new photon camera has been designed that is based on the SuperB FDIRC prototype. The full GlueX DIRC system will consist of two such cameras, with the first planned to be built and installed in 2017. We present the current status of the design and R&D, along with the future plans of the GlueX DIRC detector.

Published

2017

9. Installation and Commissioning of the GLUEX DIRC

Author

M. Patsyuk, E. Ihloff, A. Hurley, E. Chudakov, J. Kelsey, C. Fanelli, R. Dzhygadlo, G. Kalicy, M. Shepherd, J. R. Stevens, J. Hardin, J. Bessuille, T. Whitlatch, J. Schwiening, J. Frye, Yang Yang, F. Barbosa, W. Li, Marian E. Williams, and Abbas J. Ali

Subjects

Physics, Particle physics, Strange quark, Physics - Instrumentation and Detectors, GlueX, Meson, Physics::Instrumentation and Detectors, Nuclear Theory, Detector, FOS: Physical sciences, BaBar experiment, Instrumentation and Detectors (physics.ins-det), Particle identification, Detection of internally reflected Cherenkov light, High Energy Physics::Experiment, Nuclear Experiment (nucl-ex), Photon beam, Nuclear Experiment, Instrumentation, Mathematical Physics

Abstract

© 2020 IOP Publishing Ltd and Sissa Medialab. The GLUEX experiment takes place in experimental Hall D at Jefferson Lab (JLab). With a linearly polarized photon beam of up to 12 GeV energy, GLUEX is a dedicated experiment to search for hybrid mesons via photoproduction reactions. The low-intensity (Phase I) of GLUEX was recently completed; the high-intensity (Phase II) started in 2020 including an upgraded particle identification system, known as the DIRC (Detection of Internally Reflected Cherenkov light), utilizing components from the decommissioned BaBar experiment. The identification and separation of the kaon final states will significantly enhance the GLUEX physics program, by adding the capability of accessing the strange quark flavor content of conventional (and potentially hybrid) mesons. In these proceedings, we report that the installation and commissioning of the DIRC detector has been successfully completed.

Published

2020

10. Status of the GlueX DIRC

Author

J. Schwiening, Mark Richard James Williams, T. Whitlatch, J. Hardin, M. Shepherd, C. Fanelli, J. Frye, W. Li, C. Schwarz, Y. Yang, R. Dzhygadlo, J. R. Stevens, E. Chudakov, Abbas J. Ali, M. Patsyuk, F. Barbosa, G. Kalicy, J. Kelsey, A. Hurley, and J. Bessuille

Subjects

Physics, Nuclear physics, Nuclear and High Energy Physics, GlueX, Upgrade, 010308 nuclear & particles physics, Bar (music), 0103 physical sciences, Detector, 010306 general physics, 01 natural sciences, Instrumentation, Particle identification

Abstract

This year we start assembling the DIRC detector to upgrade the particle identification capabilities in the forward region of the GlueX detector in Hall D at Jefferson Lab. The main components of the GlueX DIRC are the four bar boxes (reused from the decommissioned BaBar DIRC) and two photon cameras, which were designed based on the prototype for the SuperB FDIRC. The delicate bar boxes have already arrived at JLab from SLAC, where they have been stored for the last ten years. They will be attached to the newly built photon cameras and installed in Hall D already for the 2019 spring run. We present the status of the GlueX DIRC project including the ongoing R&D and the plan for the future.

Published

2020

11. A new cryogenic apparatus to search for the neutron electric dipole moment

Author

R. J. Holt, Seppo Penttila, S. Baessler, David G. Haase, C. R. Gould, M. E. Hayden, Dipangkar Dutta, S. W. T. MacDonald, L. Barrón-Palos, E. Korobkina, R. P. Redwine, Jen-Chieh Peng, Marcus H. Mendenhall, J. Long, Z. Tang, Haiyan Gao, Steven Clayton, Ross Milner, Evgeni Tsentalovich, J. Kelsey, Robert Golub, E. Ihloff, C. Vidal, S. E. Williamson, Matthew Busch, A. T. Holley, George M. Seidel, A. Saftah, M. Behzadipour, B. W. Filippone, M. Makela, Ayman I. Hawari, I. Berkutov, C. Osthelder, C. Daurer, Ricardo Alarcon, W. Yao, A. Reid, M. Broering, C. Swank, P. R. Huffman, S. Slutsky, Musa Ahmed, J. Leggett, Liang Yang, John Ramsey, Yu. Efremenko, H. O. Meyer, M. Blatnik, R. Carr, James Maxwell, T. D. S. Stanislaus, Scott Currie, E. S. Smith, W. M. Snow, A. Lipman, Takeyasu M. Ito, N. S. Phan, A. Aleksandrova, Leah Broussard, C.-Y. Liu, X. Sun, Steve K. Lamoreaux, K. A. Dow, Nima Nouri, D. P. Kendellen, A. Matlashov, R. Dipert, L. M. Bartoszek, K. K. H. Leung, C. O'Shaughnessy, M. Karcz, C. B. Erickson, Yongsun Kim, Wanchun Wei, A. R. Young, S. K. Imam, J. Bessuille, Geoffrey Greene, R. Tavakoli Dinani, T. M. Rao, S. Sosothikul, Douglas H Beck, D. Hasell, Wolfgang Korsch, P. E. Mueller, I.F. Silvera, C. R. White, M. D. Cooper, Christopher Crawford, Nadia Fomin, W. E. Sondheim, Brad Plaster, and V. Cianciolo

Subjects

Physics, Physics - Instrumentation and Detectors, Neutron electric dipole moment, 010308 nuclear & particles physics, FOS: Physical sciences, Instrumentation and Detectors (physics.ins-det), Oak Ridge National Laboratory, 01 natural sciences, 030218 nuclear medicine & medical imaging, Superfluidity, Nuclear physics, 03 medical and health sciences, 0302 clinical medicine, Electric field, 0103 physical sciences, Limit (music), Neutron, Sensitivity (control systems), Nuclear Experiment (nucl-ex), Nuclear Experiment, Instrumentation, Mathematical Physics, Spallation Neutron Source

Abstract

© 2019 IOP Publishing Ltd and Sissa Medialab. A cryogenic apparatus is described that enables a new experiment, nEDM@SNS, with a major improvement in sensitivity compared to the existing limit in the search for a neutron Electric Dipole Moment (EDM). This apparatus uses superfluid 4He to produce a high density of Ultra-Cold Neutrons (UCN) which are contained in a suitably coated pair of measurement cells. The experiment, to be operated at the Spallation Neutron Source at Oak Ridge National Laboratory, uses polarized 3He from an Atomic Beam Source injected into the superfluid 4He and transported to the measurement cells where it serves as a co-magnetometer. The superfluid 4He is also used as an insulating medium allowing significantly higher electric fields, compared to previous experiments, to be maintained across the measurement cells. These features provide an ultimate statistical uncertainty for the EDM of 2-3× 10-28 e-cm, with anticipated systematic uncertainties below this level.

Published

2019

12. The neutron electric dipole moment experiment at the Spallation Neutron Source

Author

Scott Currie, John Ramsey, Haiyan Gao, Dipangkar Dutta, Jen-Chieh Peng, Y.J. Kim, A. Lipman, A. Matlashov, E. Ihloff, M. Blatnik, E. Korobkina, M. McCrea, P. R. Huffman, C. R. Gould, C. M. O'Shaughnessy, Brad Plaster, D. Hasell, T. Rao, Mark Makela, T. D. S. Stanislaus, Wanchun Wei, C. B. Erickson, S. Baeßler, Nima Nouri, M. E. Hayden, Liang Yang, M. Broering, Ayman I. Hawari, S. Sosothikul, Yu. Efremenko, S. E. Williamson, P. E. Mueller, L. M. Bartoszek, K. K. H. Leung, A. R. Young, L. Barrón-Palos, Seppo Penttila, J. Bessuille, Geoffrey Greene, Steve K. Lamoreaux, K. A. Dow, S. W. T. MacDonald, Leah Broussard, Douglas H Beck, M. Behzadipour, Ricardo Alarcon, W. Yao, S. Slutsky, Christopher Crawford, A. Aleksandrova, R. Tavakoli Dinani, David G. Haase, Evgeni Tsentalovich, R. J. Holt, Z. Tang, R. P. Redwine, J. Kelsey, Matthew Busch, E. Leggett, A. Saftah, Steven Clayton, Ross Milner, M. W. Ahmed, Nadia Fomin, C. Vidal, Wolfgang Korsch, V. Cianciolo, E. Smith, I.F. Silvera, C. R. White, Marcus H. Mendenhall, J. Long, R. Dipert, Robert Golub, A. T. Holley, C. Osthelder, R. Carr, W. M. Snow, George M. Seidel, B. W. Filippone, W. E. Sondheim, Takeyasu M. Ito, N. S. Phan, C. Daurer, M. D. Cooper, A. Reid, C. Swank, James Maxwell, X. Sun, Pinghan Chu, H. O. Meyer, and C.-Y. Liu

Subjects

Physics, Physics - Instrumentation and Detectors, Neutron electric dipole moment, 010308 nuclear & particles physics, QC1-999, FOS: Physical sciences, Field strength, Instrumentation and Detectors (physics.ins-det), 7. Clean energy, 01 natural sciences, Nuclear physics, Electric field, 0103 physical sciences, Electromagnetic shielding, Precession, Ultracold neutrons, Nuclear Experiment (nucl-ex), 010306 general physics, Spin (physics), Nuclear Experiment, Spallation Neutron Source

Abstract

Novel experimental techniques are required to make the next big leap in neutron electric dipole moment experimental sensitivity, both in terms of statistics and systematic error control. The nEDM experiment at the Spallation Neutron Source (nEDM@SNS) will implement the scheme of Golub & Lamoreaux [Phys. Rep., 237, 1 (1994)]. The unique properties of combining polarized ultracold neutrons, polarized $^3$He, and superfluid $^4$He will be exploited to provide a sensitivity to $\sim 10^{-28}\,e{\rm \,\cdot\, cm}$. Our cryogenic apparatus will deploy two small ($3\,{\rm L}$) measurement cells with a high density of ultracold neutrons produced and spin analyzed in situ. The electric field strength, precession time, magnetic shielding, and detected UCN number will all be enhanced compared to previous room temperature Ramsey measurements. Our $^3$He co-magnetometer offers unique control of systematic effects, in particular the Bloch-Siegert induced false EDM. Furthermore, there will be two distinct measurement modes: free precession and dressed spin. This will provide an important self-check of our results. Following five years of "critical component demonstration," our collaboration transitioned to a "large scale integration" phase in 2018. An overview of our measurement techniques, experimental design, and brief updates are described in these proceedings., Submitted to proceedings of PPNS 2018 - International Workshop on Particle physics at Neutron Sources (https://www.webofconferences.org/epj-web-of-conferences-forthcoming-conferences/1148-ppns-2018)

Published

2019

13. The Qweak experimental apparatus

Author

J. R. Hoskins, R. S. Beminiwattha, J. Birchall, J. Diefenbach, Juliette Mammei, J. Balewski, Erik Urban, J. F. Dowd, K. Johnston, G. Clark, P.W. Rose, B. Sawatzky, P. Solvignon, M. Kargiantoulakis, M. Elaasar, J. Mei, S. Sobczynski, A. Micherdzinska, A. Kubera, M. K. Jones, R.B. Zielinski, Mitchell D. Anderson, T. Averett, R. Suleiman, V. M. Gray, E. Henderson, R.D. Carlini, S. A. Wood, Neven Simicevic, J. D. Bowman, A. Mkrtchyan, Amber McCreary, Darko Androić, V. Tvaskis, E. Bonnell, N. Morgan, R. Mahurin, Kent Paschke, R. Averill, J. Beaufait, J. Roche, S. Zhamkochyan, D. J. Mack, C. A. Davis, Fatiha Benmokhtar, S. A. Page, D.C. Dean, J. M. Finn, P. Medeiros, Jean-Francois Rajotte, R. Subedi, G. D. Cates, S. Wells, F. Guo, S. MacEwan, P. Wang, J. A. Dunne, Jongmin Lee, T. Seva, E. Korkmaz, S. K. Phillips, D. C. Jones, P. Brindza, Amrendra Narayan, M. Poelker, J. Pan, J. Leacock, A. R. Lee, V. Tadevosyan, D. Gaskell, Y. Liang, R. Michaels, M. M. Dalton, D.J. Harrison, A.K. Opper, J. Grames, M. McDonald, S. Kowalski, J.C. Cornejo, W. S. Duvall, W. D. Ramsay, A. Asaturyan, J. Leckey, K. Grimm, J. W. Martin, B. Stokes, P. M. King, Michael Gericke, K. E. Mesick, H. Mkrtchyan, E. Ihloff, J. A. Magee, Nadeem A. Khan, L. Lee, J. Kelsey, Trent Allison, Jay Benesch, S. Yang, D. T. Spayde, B. Waidyawansa, D.B. Brown, S. Covrig Dusa, Dipangkar Dutta, W. R. Falk, R. Silwal, A. Subedi, Vladimir Nelyubin, J. Bessuille, D. G. Meekins, R. T. Jones, J. Hansknecht, Nuruzzaman, W. T. H. van Oers, K.D. Finelli, Michael Pitt, J.R. Echols, D. S. Armstrong, G. R. Smith, Douglas Storey, M. J. McHugh, M. H. Shabestari, J. Musson, K. A. Dow, L. Z. Ndukum, Wouter Deconinck, W.R. Roberts, William A. Tobias, and B. S. Cavness

Subjects

Physics, Nuclear and High Energy Physics, business.industry, Compton scattering, Collimator, Electron, Helicity, law.invention, Nuclear physics, Optics, Beamline, law, Scintillation counter, Cathode ray, Physics::Accelerator Physics, Parity violation, Electron scattering, Liquid hydrogen target, business, Instrumentation, Cherenkov radiation

Abstract

The Jefferson Lab Q weak experiment determined the weak charge of the proton by measuring the parity-violating elastic scattering asymmetry of longitudinally polarized electrons from an unpolarized liquid hydrogen target at small momentum transfer. A custom apparatus was designed for this experiment to meet the technical challenges presented by the smallest and most precise e → p asymmetry ever measured. Technical milestones were achieved at Jefferson Lab in target power, beam current, beam helicity reversal rate, polarimetry, detected rates, and control of helicity-correlated beam properties. The experiment employed 180 μA of 89% longitudinally polarized electrons whose helicity was reversed 960 times per second. The electrons were accelerated to 1.16 GeV and directed to a beamline with extensive instrumentation to measure helicity-correlated beam properties that can induce false asymmetries. Moller and Compton polarimetry were used to measure the electron beam polarization to better than 1%. The electron beam was incident on a 34.4 cm liquid hydrogen target. After passing through a triple collimator system, scattered electrons between 5.8° and 11.6° were bent in the toroidal magnetic field of a resistive copper-coil magnet. The electrons inside this acceptance were focused onto eight fused silica Cherenkov detectors arrayed symmetrically around the beam axis. A total scattered electron rate of about 7 GHz was incident on the detector array. The detectors were read out in integrating mode by custom-built low-noise pre-amplifiers and 18-bit sampling ADC modules. The momentum transfer Q 2 =0.025 GeV 2 was determined using dedicated low-current ( ~ 100 pA ) measurements with a set of drift chambers before (and a set of drift chambers and trigger scintillation counters after) the toroidal magnet.

Published

2015

14. Compact x-ray source based on burst-mode inverse Compton scattering at 100 kHz

Author

Sergio Carbajo, Krishna Murari, Boris Khaykovich, Sami Tantawi, Hua Lin, David E. Moncton, J. Bessuille, E. Ihloff, William Graves, Valery Dolgashev, Franz X. Kärtner, P. Brown, Kyung-Han Hong, Luis E. Zapata, G. Resta, Emilio A. Nanni, Bates Linear Accelerator Center, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Laboratory for Nuclear Science, Massachusetts Institute of Technology. Research Laboratory of Electronics, MIT Nuclear Reactor Laboratory, Graves, William S., Hong, Kyung-Han, Ihloff, Ernest E., Khaykovich, Boris, Bessuille, J., Brown, P., Lin, H., Nanni, Emilio Alessandro, Resta, G., Zapata, L. E., Kaertner, Franz X., and Moncton, David E.

Subjects

Accelerator Physics (physics.acc-ph), Nuclear and High Energy Physics, Photon, Physics and Astronomy (miscellaneous), FOS: Physical sciences, Inverse, Electron, Photon energy, 7. Clean energy, 01 natural sciences, Linear particle accelerator, law.invention, 010309 optics, Optics, law, 0103 physical sciences, lcsh:Nuclear and particle physics. Atomic energy. Radioactivity, ddc:530, Physics, 010308 nuclear & particles physics, business.industry, Compton scattering, Particle accelerator, Surfaces and Interfaces, Laser, lcsh:QC770-798, Physics::Accelerator Physics, Physics - Accelerator Physics, Atomic physics, business

Abstract

A design for a compact x-ray light source (CXLS) with flux and brilliance orders of magnitude beyond existing laboratory scale sources is presented. The source is based on inverse Compton scattering of a high brightness electron bunch on a picosecond laser pulse. The accelerator is a novel high-efficiency standing-wave linac and rf photoinjector powered by a single ultrastable rf transmitter at X-band rf frequency. The high efficiency permits operation at repetition rates up to 1 kHz, which is further boosted to 100 kHz by operating with trains of 100 bunches of 100 pC charge, each separated by 5 ns. The entire accelerator is approximately 1 meter long and produces hard x rays tunable over a wide range of photon energies. The colliding laser is a Yb∶YAG solid-state amplifier producing 1030 nm, 100 mJ pulses at the same 1 kHz repetition rate as the accelerator. The laser pulse is frequency-doubled and stored for many passes in a ringdown cavity to match the linac pulse structure. At a photon energy of 12.4 keV, the predicted x-ray flux is 5×10[superscript 11] photons/second in a 5% bandwidth and the brilliance is 2 × 10[superscript 12] photons/(sec mm[superscript 2] mrad[superscript 2] 0.1%) in pulses with rms pulse length of 490 fs. The nominal electron beam parameters are 18 MeV kinetic energy, 10 microamp average current, 0.5 microsecond macropulse length, resulting in average electron beam power of 180 W. Optimization of the x-ray output is presented along with design of the accelerator, laser, and x-ray optic components that are specific to the particular characteristics of the Compton scattered x-ray pulses., United States. Defense Advanced Research Projects Agency (Grant N66001-11-1-4192), National Science Foundation (U.S.) (Grant DMR-1042342), United States. Dept. of Energy (Grant DE-FG02-10ER46745), United States. Dept. of Energy (Grant DE-FG02-08ER41532), Center for Free-Electron Laser Science

Published

2014

15. The OLYMPUS Experiment

Author

B. Buck, H. Vardanyan, D. Rodríguez Piñeiro, M. Statera, Alexander Kiselev, O. Ates, A. Movsisyan, B. Gläser, J. Kelsey, Y. Holler, C. O'Connor, J. Diefenbach, Frank Brinker, J. R. Calarco, G. Ciullo, D. Khaneft, R. Pérez Benito, A. Thiel, D. Veretennikov, T.W. Donnelly, Ph. Hoffmeister, D. Hasell, Brian S. Henderson, R. Russell, S. Frullani, Morgan Murray, G. Rosner, G. Elbakian, P. Klassen, D. Eversheim, S. Lumsden, I. Lehmann, A. Avetisyan, R. Perrino, Paolo Lenisa, N. Akopov, N. D'Ascenzo, D. Bayadilov, O. Miklukho, J. Hauschildt, G. Karyan, J. Bessuille, D. Lenz, Alexander Schmidt, E. Cisbani, Ch. Funke, R. P. Redwine, V. Yeganov, Genady Gavrilov, Lauren Ice, V. A. Andreev, A. Krivshich, V. Carassiti, Ross Milner, Y. Naryshkin, M. Contalbrigo, Jan C. Bernauer, K. A. Dow, B. Seitz, U. Schneekloth, R. Beck, N. Görrissen, H. Marukyan, R. De Leo, A. Winnebeck, Andrey V. Izotov, C. Vidal, Michael Kohl, Ralf Kaiser, F. E. Maas, Ricardo Alarcon, S. Belostotski, and Y. Ma

Subjects

two-photon [exchange], Physics - Instrumentation and Detectors, Physics::Instrumentation and Detectors, Hadron, luminosity: monitoring, Recoil, 4-MOMENTUM TRANSFERS, Nuclear Experiment (nucl-ex), Nuclear Experiment, Instrumentation, Physics, Elastic scattering, Luminosity (scattering theory), ELECTROMAGNETIC FORM-FACTORS, Instrumentation and Detectors (physics.ins-det), elastic scattering [cross section], positron p: elastic scattering, Antimatter, drift chamber, elastic scattering [electron p], target [hydrogen], proportional chamber, CROSS-SECTION, Nuclear and High Energy Physics, ELECTRON-PROTON, DESY DORIS Stor, FOS: Physical sciences, monitoring [luminosity], time-of-flight, electron p: elastic scattering, Nuclear physics, Cross section (physics), RATIO, (GEV/C)(2), p: form factor: ratio, calorimeter, ddc:530, cross section: elastic scattering, activity report, hydrogen: target, exchange: two-photon, Scattering, POSITRONS, DESY, elastic scattering [positron p], magnetic spectrometer, PROTON ELASTIC-SCATTERING, form factor: ratio [p], gas electron multiplier, Physics::Accelerator Physics, High Energy Physics::Experiment

Abstract

Nuclear instruments & methods in physics research / A 741, 1 - 17 (2014). doi:10.1016/j.nima.2013.12.035, The OLYMPUS experiment was designed to measure the ratio between the positron-proton and electron-proton elastic scattering cross sections, with the goal of determining the contribution of two-photon exchange to the elastic cross section. Two-photon exchange might resolve the discrepancy between measurements of the proton form factor ratio, $\mu_p G^p_E/G^p_M$, made using polarization techniques and those made in unpolarized experiments. OLYMPUS operated on the DORIS storage ring at DESY, alternating between 2.01~GeV electron and positron beams incident on an internal hydrogen gas target. The experiment used a toroidal magnetic spectrometer instrumented with drift chambers and time-of-flight detectors to measure rates for elastic scattering over the polar angular range of approximately $25^\circ$--$75^\circ$. Symmetric M{\o}ller/Bhabha calorimeters at $1.29^\circ$ and telescopes of GEM and MWPC detectors at $12^\circ$ served as luminosity monitors. A total luminosity of approximately 4.5~fb$^{-1}$ was collected over two running periods in 2012. This paper provides details on the accelerator, target, detectors, and operation of the experiment., Published by North-Holland Publ. Co., Amsterdam

Published

2013

16. The GlueX DIRC project

Author

Tim Whitlatch, R. Dzhygadlo, J. Hardin, J. R. Stevens, J. Schwiening, M. Patsyuk, J. Kelsey, J. Bessuille, E. Chudakov, J. Frye, Carsten Schwartz, Fernando Barbosa, M. Shepherd, C. Fanelli, and Michael Williams

Subjects

Physics, Particle physics, Physics - Instrumentation and Detectors, GlueX, Meson, Physics::Instrumentation and Detectors, 010308 nuclear & particles physics, High Energy Physics::Lattice, High Energy Physics::Phenomenology, Detector, FOS: Physical sciences, Instrumentation and Detectors (physics.ins-det), 01 natural sciences, Particle identification, Detection of internally reflected Cherenkov light, 0103 physical sciences, High Energy Physics::Experiment, Nuclear Experiment (nucl-ex), Photon beam, Nuclear Experiment, 010306 general physics, Instrumentation, Mathematical Physics

Abstract

The GlueX experiment was designed to search for and study the pattern of gluonic excitations in the meson spectrum produced through photoproduction reactions at a new tagged photon beam facility in Hall D at Jefferson Laboratory. The particle identification capabilities of the GlueX experiment will be enhanced by constructing a DIRC (Detection of Internally Reflected Cherenkov light) detector, utilizing components of the decommissioned BaBar DIRC. The DIRC will allow systematic studies of kaon final states that are essential for inferring the quark flavor content of both hybrid and conventional mesons. The design for the GlueX DIRC is presented, including the new expansion volumes that are currently under development., 8 pages, 6 figures

Published

2016

17. STATUS OF HIGH INTENSITY POLARIZED ELECTRON GUN AT MIT-BATES

Author

Evgeni Tsentalovich, J. Bessuille, and M. Tiunov

Subjects

Physics, Optics, business.industry, High intensity, BATES, business, Electron gun

Published

2011

18. Measurement of the Charge-Averaged Elastic Lepton-Proton Scattering Cross Section by the OLYMPUS Experiment.

Author

Bernauer JC, Schmidt A, Henderson BS, Ice LD, Khaneft D, O'Connor C, Russell R, Akopov N, Alarcon R, Ates O, Avetisyan A, Beck R, Belostotski S, Bessuille J, Brinker F, Calarco JR, Carassiti V, Cisbani E, Ciullo G, Contalbrigo M, De Leo R, Diefenbach J, Donnelly TW, Dow K, Elbakian G, Eversheim PD, Frullani S, Funke C, Gavrilov G, Gläser B, Görrissen N, Hasell DK, Hauschildt J, Hoffmeister P, Holler Y, Ihloff E, Izotov A, Kaiser R, Karyan G, Kelsey J, Kiselev A, Klassen P, Krivshich A, Kohl M, Lehmann I, Lenisa P, Lenz D, Lumsden S, Ma Y, Maas F, Marukyan H, Miklukho O, Milner RG, Movsisyan A, Murray M, Naryshkin Y, Perez Benito R, Perrino R, Redwine RP, Rodríguez Piñeiro D, Rosner G, Schneekloth U, Seitz B, Statera M, Thiel A, Vardanyan H, Veretennikov D, Vidal C, Winnebeck A, and Yeganov V

Abstract

We report the first measurement of the average of the electron-proton and positron-proton elastic scattering cross sections. This lepton charge-averaged cross section is insensitive to the leading effects of hard two-photon exchange, giving more robust access to the proton's electromagnetic form factors. The cross section was extracted from data taken by the OLYMPUS experiment at DESY, in which alternating stored electron and positron beams were scattered from a windowless gaseous hydrogen target. Elastic scattering events were identified from the coincident detection of the scattered lepton and recoil proton in a large-acceptance toroidal spectrometer. The luminosity was determined from the rates of Møller, Bhabha, and elastic scattering in forward electromagnetic calorimeters. The data provide some selectivity between existing form factor global fits and will provide valuable constraints to future fits.

Published

2021

19. Hard Two-Photon Contribution to Elastic Lepton-Proton Scattering Determined by the OLYMPUS Experiment.

Author

Henderson BS, Ice LD, Khaneft D, O'Connor C, Russell R, Schmidt A, Bernauer JC, Kohl M, Akopov N, Alarcon R, Ates O, Avetisyan A, Beck R, Belostotski S, Bessuille J, Brinker F, Calarco JR, Carassiti V, Cisbani E, Ciullo G, Contalbrigo M, De Leo R, Diefenbach J, Donnelly TW, Dow K, Elbakian G, Eversheim PD, Frullani S, Funke C, Gavrilov G, Gläser B, Görrissen N, Hasell DK, Hauschildt J, Hoffmeister P, Holler Y, Ihloff E, Izotov A, Kaiser R, Karyan G, Kelsey J, Kiselev A, Klassen P, Krivshich A, Lehmann I, Lenisa P, Lenz D, Lumsden S, Ma Y, Maas F, Marukyan H, Miklukho O, Milner RG, Movsisyan A, Murray M, Naryshkin Y, Perez Benito R, Perrino R, Redwine RP, Rodríguez Piñeiro D, Rosner G, Schneekloth U, Seitz B, Statera M, Thiel A, Vardanyan H, Veretennikov D, Vidal C, Winnebeck A, and Yeganov V

Abstract

The OLYMPUS Collaboration reports on a precision measurement of the positron-proton to electron-proton elastic cross section ratio, R&#95;{2γ}, a direct measure of the contribution of hard two-photon exchange to the elastic cross section. In the OLYMPUS measurement, 2.01 GeV electron and positron beams were directed through a hydrogen gas target internal to the DORIS storage ring at DESY. A toroidal magnetic spectrometer instrumented with drift chambers and time-of-flight scintillators detected elastically scattered leptons in coincidence with recoiling protons over a scattering angle range of ≈20° to 80°. The relative luminosity between the two beam species was monitored using tracking telescopes of interleaved gas electron multiplier and multiwire proportional chamber detectors at 12°, as well as symmetric Møller or Bhabha calorimeters at 1.29°. A total integrated luminosity of 4.5  fb^{-1} was collected. In the extraction of R&#95;{2γ}, radiative effects were taken into account using a Monte Carlo generator to simulate the convolutions of internal bremsstrahlung with experiment-specific conditions such as detector acceptance and reconstruction efficiency. The resulting values of R&#95;{2γ}, presented here for a wide range of virtual photon polarization 0.456<ε<0.978, are smaller than some hadronic two-photon exchange calculations predict, but are in reasonable agreement with a subtracted dispersion model and a phenomenological fit to the form factor data.

Published

2017