10 results on '"Reinhard Brinkmann"'
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2. Report of the Snowmass 2021 Collider Implementation Task Force
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Thomas Roser, Reinhard Brinkmann, Sarah Cousineau, Dmitri Denisov, Spencer Gessner, Steve Gourlay, Philippe Lebrun, Meenakshi Narain, Katsunobu Oide, Tor Raubenheimer, John Seeman, Vladimir Shiltsev, Jim Strait, Marlene Turner, and Lian-Tao Wang
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Accelerator Physics (physics.acc-ph) ,High Energy Physics - Experiment (hep-ex) ,accelerator ,lepton ,costs ,FOS: Physical sciences ,Physics - Accelerator Physics ,acceleration ,hadron ,particle source ,performance ,High Energy Physics - Experiment - Abstract
The Snowmass 2021 Implementation Task Force has been established to evaluate the proposed future accelerator projects for performance, technology readiness, schedule, cost, and environmental impact. Corresponding metrics has been developed for uniform comparison of the proposals ranging from Higgs/EW factories to multi-TeV lepton, hadron and ep collider facilities, based on traditional and advanced acceleration technologies. This report documents the metrics and processes, and presents evaluations of future colliders performed by Implementation Task Force., Comment: 68 pages; Submitted to the Proceedings of the US Community Study on the Future of Particle Physics (Snowmass 2021)
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- 2022
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3. SINBAD-ARES - A Photo-Injector for External Injection Experiments in Novel Accelerators at DESY
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Ulrich Dorda, Florian Burkart, Francois Lemery, Farzad Jafarinia, Reinhard Brinkmann, Daniel Marx, M. Huening, E. Panofski, Paul Andreas Walker, Holger Schlarb, Sonja Jaster-Merz, Ralph Assmann, Sumera Yamin, Thomas Vinatier, Wolfgang Hillert, Barbara Marchetti, Frank Mayet, Lutz Winkelmann, Max Kellermeier, Klaus Floettmann, Willi Kuropka, Ingmar Hartl, and Sven Pfeiffer
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History ,Materials science ,business.industry ,Optoelectronics ,Physics::Accelerator Physics ,DESY ,ddc:530 ,business ,Photo injector ,Computer Science Applications ,Education - Abstract
4th European Advanced Accelerator Concepts Workshop, EAAC19, Isola d'Elba, Italy, 15 Sep 2019 - 20 Sep 2019; Journal of physics / Conference Series 1596, 012036 (2020). doi:10.1088/1742-6596/1596/1/012036, The accelerator R&D facility SINBAD (Short Innovative Bunches and Accelerators at DESY) will drive multiple independent experiments in the fields of production of ultra-short electron bunches and tests of advanced high gradient acceleration concepts.The SINBAD-ARES (Accelerator Research Experiment at SINBAD) linac has been designed to allow the production of high brightness ultra-short electron bunches with excellent arrival-time stability. The accelerator will be used to study experimentally the optimization of the brightness for fs long electron bunches. Such electron bunches, with tunable characteristics, will be then injected into novel accelerators realized in the context of the ATHENA project, the ACHIP international collaboration and the ARIES program. In this paper we describe the principal characteristics of the linac design, we underline the technical challenges connected to the production and characterization of fs bunches and we report on the status of the installation and commissioning., Published by IOP Publ., Bristol
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- 2020
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4. Design status of the ultra-low emittance synchrotron facility PETRA IV
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Hung-Chun Chao, Markus Tischer, Yong-Chul Chae, Xavier Gavaldà, E. Weckert, Ralf Röhlsberger, Rainer Wanzenberg, Reinhard Brinkmann, Christian G. Schroer, Joachim Keil, Ilya Agapov, and W. Brefeld
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Diffraction ,Physics ,Low emittance ,business.industry ,DESY ,Synchrotron light source ,Synchrotron ,law.invention ,Upgrade ,Light source ,Optics ,law ,ddc:530 ,Thermal emittance ,business - Abstract
13th International Conference on Synchrotron Radiation Instrumentation, SRI2018, Taipei, Taiwan, 10 Jun 2018 - 15 Jun 2018; AIP conference proceedings 2054(1), 030002 (2019). doi:10.1063/1.5084565, At DESY the Synchrotron Light Source PETRA III offers scientists outstanding opportunities for experiments with hard X-rays of exceptionally high brilliance since 2009. Research activities have been started to upgrade PETRA III to the ultra-low emittance source PETRA IV, which will be diffraction limited up to the hard X-ray range. Therefore the future light source PETRA IV will be ideal for 3D X-ray microscopy of biological, chemical, and physical processes under realistic conditions at length scales from atomic dimensions to millimeters. The lattice design is aiming for a horizontal emittance in the range between 10 pm rad and 30 pm rad at a beam energy of 6 GeV. Presently, two different approaches are considered for the lattice design: a design based on a hybrid multibend achromat with an interleaved sextupole configuration based on the ESRF-EBS design, and a lattice with a double non-interleaved sextupole configuration. The current status of the design activities is reported including the injector and several technical aspects., Published by AIP, Melville, NY
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- 2019
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5. Electron-beam manipulation techniques in the SINBAD Linac for external injection in plasma wake-field acceleration
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Holger Schlarb, M. Huening, Ralph Assmann, Reinhard Brinkmann, Jun Zhu, Klaus Floettmann, Ingmar Hartl, Ulrich Dorda, Christopher Behrens, Yuancun Nie, and Barbara Marchetti
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Physics ,Nuclear and High Energy Physics ,010308 nuclear & particles physics ,business.industry ,DESY ,Plasma acceleration ,01 natural sciences ,Linear particle accelerator ,Acceleration ,Optics ,Bunches ,0103 physical sciences ,Cathode ray ,Physics::Accelerator Physics ,ddc:530 ,Laser beam quality ,010306 general physics ,business ,Instrumentation ,Beam (structure) - Abstract
2nd European Advanced Accelerator Concepts Workshop 2015, EAAC 2015, La Biodola, Elba, Italy, 13 Sep 2015 - 19 Sep 2015 ; Nuclear instruments & methods in physics research / A 829, 278 - 283(2016). doi:10.1016/j.nima.2016.03.041, The SINBAD facility(Short and INnovative Bunches and Accelerators at Desy)is foreseen to host various experiments in the field of production of ultra-short electron bunches and novel high gradient acceleration techniques. Besides studying novel acceleration techniques aiming to produce high brightness short electron bunches, the ARD group at DESY is working on the design of a conventional RF accelerator that will allow the production of low charge (0.5pC – fewpC) ultra-short electron bunches (having full width half maximum, FWHM, length r 1 fs – fewfs). The setup will allow the direct experimental comparison of the performance achievable by using different compression techniques (velocity bunching, magnetic compression, hybrid compression schemes). At a later stage the SINBAD linac will be used to inject such electron bunches into a laser driven Plasma Wakefield Accelerator,which imposes strong requirements on parameters such as the arrival time jitter and the pointing stability of the beam. In this paper we review the compression techniques that are foreseen at SINBAD and we underline the differences in terms of peak current, beam quality and arrival time stability., Published by North-Holland Publ. Co., Amsterdam
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- 2016
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6. WG3 Summary: Electron beams from electromagnetic structures, including dielectric and photonics structures
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Reinhard Brinkmann and David Alesini
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History ,Materials science ,business.industry ,Optoelectronics ,Electron ,Dielectric ,Photonics ,business ,Computer Science Applications ,Education - Abstract
This summary provides a brief overview of the presentations and discussions during the sessions of working group 3 at the EAAC2019 workshop.
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- 2020
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7. Noninterleaved round beam lattice for light sources
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Reinhard Brinkmann, Joachim Keil, Ilya Agapov, and Rainer Wanzenberg
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Physics ,Nuclear and High Energy Physics ,Low emittance ,Physics and Astronomy (miscellaneous) ,010308 nuclear & particles physics ,business.industry ,Surfaces and Interfaces ,01 natural sciences ,Dynamic aperture ,Optics ,Lattice (order) ,0103 physical sciences ,lcsh:QC770-798 ,Physics::Accelerator Physics ,ddc:530 ,lcsh:Nuclear and particle physics. Atomic energy. Radioactivity ,010306 general physics ,business ,Beam (structure) - Abstract
Physical review accelerators and beams 21(5), 051601 (2018). doi:10.1103/PhysRevAccelBeams.21.051601, A conceptual design and performance of a round beam lattice for synchrotron light sources based on the phase space exchange principle and the noninterleaved sextupole distribution is presented. Optics design is performed for an approximately 30 pm emittance 6 GeV machine of 2300 m circumference which combines cells with and without straight sections for the insertion devices., Published by American Physical Society, College Park, MD
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- 2018
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8. PETRA IV: the ultralow-emittance source project at DESY
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Rainer Wanzenberg, W. Brefeld, Hung-Chun Chao, Mikael Eriksson, Michael Sprung, Reinhard Brinkmann, Ralf Röhlsberger, Markus Tischer, Yong Chul Chae, Christian G. Schroer, Joachim Keil, E. Weckert, Ilya Agapov, Xavier Gavaldà, and Oliver H. Seeck
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0301 basic medicine ,Diffraction ,030103 biophysics ,Nuclear and High Energy Physics ,Radiation ,Computer science ,Synchrotron Radiation Source ,DESY ,02 engineering and technology ,021001 nanoscience & nanotechnology ,Engineering physics ,03 medical and health sciences ,Conceptual design ,ddc:540 ,Physics::Accelerator Physics ,Thermal emittance ,0210 nano-technology ,Instrumentation - Abstract
Journal of synchrotron radiation 25(5), 1277 - 1290 (2018). doi:10.1107/S1600577518008858, The PETRA IV project aims at upgrading the present synchrotron radiation source PETRA III at DESY into an ultralow-emittance source. Being diffraction limited up to X-rays of about 10 keV, PETRA IV will be ideal for three-dimensional X-ray microscopy of biological, chemical and physical processes under realistic conditions at length scales from atomic dimensions to millimetres and time scales down to the sub-nanosecond regime. In this way, it will enable groundbreaking studies in many fields of science and industry, such as health, energy, earth and environment, mobility and information technology. The science case is reviewed and the current state of the conceptual design is summarized, discussing a reference lattice, a hybrid multi-bend achromat with an interleaved sextupole configuration based on the ESRF-EBS design, in more detail as well as alternative lattice concepts., Published by IUCr, Chester
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- 2018
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9. SINBAD—The accelerator R&D facility under construction at DESY
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Reinhard Brinkmann, Arya Fallahi, Jens Osterhoff, Holger Schlarb, Ralph Assmann, Jun Zhu, Ingmar Hartl, Yuancun Nie, Klaus Flöttmann, M. Hüning, Barbara Marchetti, Franz X. Kärtner, Ulrich Dorda, and Andreas Maier
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Physics ,Nuclear and High Energy Physics ,010308 nuclear & particles physics ,DESY ,USable ,01 natural sciences ,Linear particle accelerator ,Bunches ,0103 physical sciences ,Systems engineering ,ddc:530 ,010306 general physics ,Instrumentation ,Host (network) - Abstract
2nd European Advanced Accelerator Concepts Workshop, EAAC2015, La Biodola, Isola d'Elba, Italy, 13 Sep 2015 - 19 Sep 2015; Nuclear instruments & methods in physics research / A 829, 233-236 (2016). doi:10.1016/j.nima.2016.01.067, The SINBAD facility (Short INnovative Bunches and Accelerators at DESY) is a long-term dedicated accelerator research and development facility currently under construction at DESY. It will be located in the premises of the old DORIS accelerator complex and host multiple independent experiments cost-effectively accessing the same central infrastructure like a central high power laser. With the removal of the old DORIS accelerator being completed, the refurbishment of the technical infrastructure is currently starting up.The presently ongoing conversion of the area into the SINBAD facility and the currently foreseen layout is described. The first experiment will use a compact S-band linac for the production of ultra-short bunches at hundred MeV. Once established, one of the main usages will be to externally inject electrons into a laser-driven plasma wakefield accelerator to boost the energy to GeV-level while maintaining a usable beam quality, ultimately aiming to drive an FEL. The second experiment already under planning is the setup of an attosecond radiation source with advanced technology. Further usage of the available space and infrastructure is revised and national and international collaborations are being established., Published by North-Holland Publ. Co., Amsterdam
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- 2016
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10. Observation of High Transformer Ratio Plasma Wakefield Acceleration
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Yves Renier, Timon Mehrling, Ye Chen, Reinhard Brinkmann, Houjun Qian, Frank Stephan, David Melkumyan, Anne Oppelt, G. Asova, Alberto Martinez de la Ossa, Jens Osterhoff, Matthias Gross, Florian Grüner, Prach Boonpornprasert, Quantang Zhao, James Good, O. Lishilin, Holger Huck, Davit Kalantaryan, Johannes Engel, Valentin Wohlfarth, Mikhail Krasilnikov, Carmen Tenholt, and Gregor Loisch
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General Physics ,General Physics and Astronomy ,Electron ,01 natural sciences ,Mathematical Sciences ,law.invention ,Acceleration ,Engineering ,law ,Physics::Plasma Physics ,0103 physical sciences ,ddc:550 ,010306 general physics ,Transformer ,Physics ,010308 nuclear & particles physics ,Plasma ,Plasma acceleration ,Accelerators and Storage Rings ,Computational physics ,Wavelength ,Bunches ,Physical Sciences ,Cathode ray ,Physics::Accelerator Physics - Abstract
Physical review letters 121(6), 064801 (2018). doi:10.1103/PhysRevLett.121.064801, Particle-beam-driven plasma wakefield acceleration (PWFA) enables various novel high-gradient techniques for powering future compact light-source and high-energy physics applications. Here, a driving particle bunch excites a wakefield response in a plasma medium, which may rapidly accelerate a trailing witness beam. In this Letter, we present the measurement of ratios of acceleration of the witness bunch to deceleration of the driver bunch, the so-called transformer ratio, significantly exceeding the fundamental theoretical and thus far experimental limit of 2 in a PWFA. An electron bunch with ramped current profile was utilized to accelerate a witness bunch with a transformer ratio of $4.6^{+2.2}_{−0.7}$ in a plasma with length $∼10 cm$, also demonstrating stable transport of driver bunches with lengths on the order of the plasma wavelength., Published by APS, College Park, Md.
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