Your search keyword '"Assmann, Ralph"' showing total 12 results

1. Preface of the IPAC23 Proceedings.

Author

Assmann, Ralph W.

Published

2023

2. Progress in Hybrid Plasma Wakefield Acceleration.

Author

Hidding, Bernhard, Assmann, Ralph, Bussmann, Michael, Campbell, David, Chang, Yen-Yu, Corde, Sébastien, Cabadağ, Jurjen Couperus, Debus, Alexander, Döpp, Andreas, Gilljohann, Max, Götzfried, J., Foerster, F. Moritz, Haberstroh, Florian, Habib, Fahim, Heinemann, Thomas, Hollatz, Dominik, Irman, Arie, Kaluza, Malte, Karsch, Stefan, and Kononenko, Olena

Subjects

PLASMA acceleration, LASER pulses, PLASMA accelerators, ELECTRON beams, PARTICLE beams, PARTICLE acceleration, RADIATION sources

Abstract

Plasma wakefield accelerators can be driven either by intense laser pulses (LWFA) or by intense particle beams (PWFA). A third approach that combines the complementary advantages of both types of plasma wakefield accelerator has been established with increasing success over the last decade and is called hybrid LWFA→PWFA. Essentially, a compact LWFA is exploited to produce an energetic, high-current electron beam as a driver for a subsequent PWFA stage, which, in turn, is exploited for phase-constant, inherently laser-synchronized, quasi-static acceleration over extended acceleration lengths. The sum is greater than its parts: the approach not only provides a compact, cost-effective alternative to linac-driven PWFA for exploitation of PWFA and its advantages for acceleration and high-brightness beam generation, but extends the parameter range accessible for PWFA and, through the added benefit of co-location of inherently synchronized laser pulses, enables high-precision pump/probing, injection, seeding and unique experimental constellations, e.g., for beam coordination and collision experiments. We report on the accelerating progress of the approach achieved in a series of collaborative experiments and discuss future prospects and potential impact. [ABSTRACT FROM AUTHOR]

Published

2023

3. Physics for health.

Author

Assmann, Ralph W., Cerullo, Giulio, and Ritort, Felix

Subjects

PARTICLE physics, MEDICAL physics, PHYSICS research, WELL-being

Abstract

The fundamental research on the physics of elementary particles and nature's fundamental forces led to numerous spin-offs and has tremendously helped human well-being and health. This is the subject of Chapter 4 of the EPS Challenges for Physics. [ABSTRACT FROM AUTHOR]

Published

2022

4. Commissioning Results and Electron Beam Characterization with the S-Band Photoinjector at SINBAD-ARES.

Author

Panofski, Eva, Assmann, Ralph, Burkart, Florian, Dorda, Ulrich, Genovese, Luca, Jafarinia, Farzad, Jaster-Merz, Sonja, Kellermeier, Max, Kuropka, Willi, Lemery, Francois, Marchetti, Barbara, Marx, Daniel, Mayet, Frank, Vinatier, Thomas, and Yamin, Sumera

Subjects

ELECTRON beams, MOMENTUM (Mechanics), ELECTRON accelerators, INJECTORS, INDUSTRIAL applications

Abstract

Over the years, the generation and acceleration of ultra-short, high quality electron beams has attracted more and more interest in accelerator science. Electron bunches with these properties are necessary to operate and test novel diagnostics and advanced high-gradient accelerating schemes, such as plasma accelerators and dielectric laser accelerators. Furthermore, several medical and industrial applications require high-brightness electron beams. The dedicated R&D facility ARES at DESY (Deutsches Elektronen-Synchrotron) will provide such probe beams in the upcoming years. After the setup of the normal-conducting, radio-frequency (RF) photoinjector and linear accelerating structures, ARES successfully started the beam commissioning of the RF gun. This paper gives an overview of the ARES photoinjector setup and summarizes the results of the gun commissioning process. The quality of the first electron beams is characterized in terms of charge, momentum, momentum spread and beam size. Additionally, the dependencies of the beam parameters on RF settings are described. All measurement results of the characterized beams fulfill the requirements for operating the ARES linac with this RF photoinjector. [ABSTRACT FROM AUTHOR]

Published

2021

5. IPAC20, the First Virtual International Particle Accelerator Conference.

Author

Seidel, Mike, Aßmann, Ralph, and Chautard, Frédéric

Subjects

PARTICLE accelerators, PARTICLE physics, PARTICLES (Nuclear physics), NUCLEAR counters, NUCLEAR energy, NUCLEAR medicine

Abstract

The IPAC20 story began in February 2015 when the Grand Accélérateur National d'Ions Lourds (GANIL) in Caen, France decided for the second time to bid to host the prestigious International Particle Accelerator Conference (IPAC) conference, bringing together 1,300 members of the particle accelerator community. Novikov I NRC Kurchatov Institute-PNPI i Graph V. I. Zherebchevsky I St. Petersburg State University i Humanity and Physics Meet at Tenth Tastes of Nuclear Physics For the last 10 years, the Tastes of Nuclear Physics has served as one of South Africa's most successful conferences on fundamental nuclear physics and applications. The main goals are enthusing South African students toward their highest education and physics achievements by attracting world-class speakers to instruct them on timely topics in nuclear physics and nuclear astrophysics. [Extracted from the article]

Published

2021

6. Simulation studies for characterizing ultrashort bunches using novel polarizable X-band transverse deflection structures.

Author

Marx, Daniel, Assmann, Ralph W., Craievich, Paolo, Floettmann, Klaus, Grudiev, Alexej, and Marchetti, Barbara

Subjects

ELECTRON accelerators, FEMTOSECOND lasers, DEFLECTION (Light), IMAGE reconstruction, ULTRASHORT laser pulses

Abstract

Transverse deflection structures are useful devices for characterizing the longitudinal properties of bunches in electron accelerators. With efforts to produce ever-shorter bunches for applications such as external injection into novel accelerator structures, e.g. plasma cells or dielectric structures, the applicability of deflection structures to measuring ultrashort bunches has been considered. In this paper, charge-density and bunch-length measurements of femtosecond and subfemtosecond bunches at the ARES linac at the SINBAD facility at DESY are studied with simulations and the limitations discussed in detail. The novel polarizable X-band transverse deflection structure (PolariX-TDS) will allow the streaking of bunches at all transverse angles, making a 3D charge-density reconstruction of bunches possible, in addition to the standard 1D charge-density reconstruction and bunch-length measurements. These various measurements of the charge-density distributions of bunches have been simulated, and it is shown that useful information about ultrashort bunches down to subfemtosecond lengths may be obtained using the setup planned for the ARES linac. [ABSTRACT FROM AUTHOR]

Published

2019

7. Intrinsic energy spread and bunch length growth in plasma-based accelerators due to betatron motion.

Author

Ferran Pousa, Angel, Martinez de la Ossa, Alberto, and Assmann, Ralph W.

Abstract

Plasma-based accelerators (PBAs), having demonstrated the production of GeV electron beams in only centimetre scales, offer a path towards a new generation of highly compact and cost-effective particle accelerators. However, achieving the required beam quality, particularly on the energy spread for applications such as free-electron lasers, remains a challenge. Here we investigate fundamental sources of energy spread and bunch length in PBAs which arise from the betatron motion of beam electrons. We present an analytical theory, validated against particle-in-cell simulations, which accurately describes these phenomena. Significant impact on the beam quality is predicted for certain configurations, explaining previously observed limitations on the achievable bunch length and energy spread. Guidelines for mitigating these contributions towards high-quality beams are deduced. [ABSTRACT FROM AUTHOR]

Published

2019

8. Conceptual and Technical Design Aspects of Accelerators for External Injection in LWFA.

Author

Marchetti, Barbara, Assmann, Ralph, Dorda, Ulrich, and Zhu, Jun

Subjects

PARTICLE beam bunching, BEAM dynamics

Abstract

Laser driven Wake-Field Acceleration (LWFA) has proven its capability of accelerating electron bunches (e-bunches) to up to 4 GeV energy in a single stage while reaching gradients up to hundreds of GV/m. Because of the short period of the accelerating field (typically ranging from 100 fs to 1 ps duration) and the requirement of extremely small beam size (typically smaller than 1 μ m) to match the channel, e-bunches can reach extremely high densities. They can be either extracted directly from the plasma or externally injected. The study of the external injection is interesting for two main reasons. On the one hand this method allows better control of the quality of the input beam and on the other hand it is in general necessary when a staged approach of the accelerator is considered. The interest in producing, characterizing and transporting high brightness ultra-short e-bunches has grown together with the interest in LWFA and other novel high-gradient acceleration techniques. In this paper we will review the principal techniques for producing and shaping ultra-short electron bunches with the example of the SINBAD-ARES (Accelerator Research Experiment at SINBAD) linac at the Deutsches Elektronen-Synchrotron (DESY). Our goal is to show how the design of the SINBAD-ARES linac satisfies the requirements for generating high brightness LWFA probes. In the last part of the paper we shall also comment on the technical challenges for electron control and characterization. [ABSTRACT FROM AUTHOR]

Published

2018

9. Generation of warm dense matter and strongly coupled plasmas using the High Radiation on Materials facility at the CERN Super Proton Synchrotron.

Author

Tahir, Naeem A., Schmidt, Ruediger, Brugger, Markus, Assmann, Ralph, Shutov, Alexander, Lomonosov, Igor V., Gryaznov, Viktor, Piriz, Antonio Roberto, Udrea, Serban, Hoffmann, Dieter H. H., Fortov, Vladimir E., and Deutsch, Claude

Subjects

PLASMA radiation, PROTON synchrotrons, HIGH temperature plasmas, PLASMA gases, ENERGY dissipation, ATOMS

Abstract

A dedicated facility named High Radiation on Materials (HiRadMat) is being constructed at CERN to study the interaction of the 450 GeV protons generated by the Super Proton Synchrotron (SPS) with fixed solid targets of different materials. The main purpose of these future experiments is to study the generation and propagation of thermal shock waves in the target in order to assess the damage caused to the equipment, including collimators and absorbers, in case of an accident involving an uncontrolled release of the entire beam at a given point. Detailed numerical simulations of the beam-target interaction of several cases of interest have been carried out. In this paper we present simulations of the thermodynamic and the hydrodynamic response of a solid tungsten cylindrical target that is facially irradiated with the SPS beam with nominal parameters. These calculations have been carried out in two steps. First, the energy loss of the protons is calculated in the solid target using the FLUKA code [Fasso et al., “FLUKA: A multi-particle transport code,” Report Nos. CERN-2005-10, INFN/TC-05/11, and SLAC-R-773, 2005; Fasso et al., Conference on Computing in High Energy and Nuclear Physics, La Jolla, CA, 24–28 March 2003] and this energy loss data is used as input to a sophisticated two-dimensional hydrodynamic code, BIG2 [Fortov et al., Nucl. Sci. Eng. 123, 169 (1996)], which is based on a Godunov-type numerical scheme. The transverse intensity distribution in the beam focal spot is Gaussian. We consider three different sizes of the focal spot that are characterized by standard deviations, σ=0.088, 0.28, and 0.88 mm, respectively. This study has shown that the target is severely damaged in all the three cases and the material in the beam-heated region is transformed into warm dense matter including a strongly coupled plasma state. This new experimental facility can therefore also be used for dedicated experiments to study high energy density matter. [ABSTRACT FROM AUTHOR]

Published

2009

10. Highly scalable multicycle THz production with a homemade periodically poled macrocrystal.

Author

Lemery, François, Vinatier, Thomas, Mayet, Frank, Aßmann, Ralph, Baynard, Elsa, Demailly, Julien, Dorda, Ulrich, Lucas, Bruno, Pandey, Alok-Kumar, and Pittman, Moana

Subjects

LIFE sciences, MATERIALS science, PARTICLE accelerators, INVESTMENT analysis, QUANTUM mechanics

Abstract

The THz regime is widely appealing across many disciplines including solid-state physics, life sciences, and increasingly in particle acceleration. Multicycle THz pulses are typically formed via optical rectification in periodically poled crystals. However the manufacturing procedures of these crystals limit their apertures to below ~1 cm, which from damage limitations of the crystal, limits the total pump power which can be employed, and ultimately, the total THz power which can be produced. Here we report on the simple in-house fabrication of a periodically poled crystal using ~300 μm thick wafers. Each wafer is consecutively rotated by 180∘ to support quasi-phase matching. We validate the concept with a Joule-class laser system operating at 10 Hz and measure up to 1.3 mJ of energy at 160 GHz, corresponding to an average peak power of approximately 35 MW and a conversion efficiency of 0.14%. In addition, a redshifting of the pump spectrum of ~50 nm is measured. Our results indicate that high-power THz radiation can be produced with existing and future high-power lasers in a scalable way, setting a course toward multi-gigawatt multicycle THz pulses. Multicycle pulsed Terahertz radiation has appealing applications in medicine, applications in medicine, biology, material science, and could power emerging laser-based table-top accelerators and diagnostics. However a simple way to generate such pulses with high energy is not straightforward. The authors report on generation of high-peak-intensity THz pulses using a Lithium-Niobate wafer-chain and achieving a 35 megawatt in peak intensity. [ABSTRACT FROM AUTHOR]

Published

2020

11. Plasma acceleration with external injection at SINBAD.

Author

Grebenyuk, Julia, Assmann, Ralph, Dorda, Ulrich, and Marchetti, Barbara

Published

2014

12. Refraction of a particle beam.

Author

Muggli, Patric, Lee, Seung, Katsouleas, Thomas, Assmann, Ralph, Decker, Franz-Joseph, Hogan, Mark J., Iverson, Richard, Raimondi, Pantaleo, Siemann, Robert H., Walz, Dieter, Blue, Brent, Clayton, Christophr E., Dodd, Evan, Fonseca, Ricardo A., Hemker, Roy, Joshi, Chandrashekhar, Marsh, Kenneth A., Mori, Warren B., and Wang, Shoquin

Subjects

PARTICLE beams, REFRACTION (Optics), OPTICAL reflection

Abstract

Discusses how particle beam can be refracted and internally reflected. Causes of refraction; Magnitude of deflection; Photographs of sample results.

Published

2001