Your search keyword '"Lindstrom, C."' showing total 10 results

1. Development of a nonlinear plasma lens for achromatic beam transport

Author

Drobniak, P., Adli, E., Anderson, H. Bergravf, Dyson, A., Mewes, S. M., Sjobak, K. N., Thévenet, M., and Lindstrøm, C. A.

Subjects

Physics - Accelerator Physics, Physics - Plasma Physics

Abstract

We introduce the new idea of a nonlinear active plasma lens, as part of a larger transport lattice for achromatic electron beam transport. The proposed implementation is based on using the Hall effect in a plasma and is motivated by 1D-hydrodynamic simulations. The manufactured design is presented, including its undergoing experimental characterisation on the CLEAR beam-line at CERN., Comment: 16 pages, 10 figures, submitted to AAC 2024 conference proceedings

Published

2024

2. Emittance preservation in a plasma-wakefield accelerator

Author

Lindstrøm, C. A., Beinortaitė, J., Svensson, J. Björklund, Boulton, L., Chappell, J., Diederichs, S., Foster, B., Garland, J. M., Caminal, P. González, Loisch, G., Peña, F., Schröder, S., Thévenet, M., Wesch, S., Wing, M., Wood, J. C., D'Arcy, R., and Osterhoff, J.

Subjects

Physics - Accelerator Physics

Abstract

Radio-frequency particle accelerators are engines of discovery, powering high-energy physics and photon science, but are also large and expensive due to their limited accelerating fields. Plasma-wakefield accelerators (PWFAs) provide orders-of-magnitude stronger fields in the charge-density wave behind a particle bunch travelling in a plasma, promising particle accelerators of greatly reduced size and cost. However, PWFAs can easily degrade the beam quality of the bunches they accelerate. Emittance, which determines how tightly beams can be focused, is a critical beam quality in for instance colliders and free-electron lasers, but is particularly prone to degradation. We demonstrate, for the first time, emittance preservation in a high-gradient and high-efficiency PWFA while simultaneously preserving charge and energy spread. This establishes that PWFAs can accelerate without degradation$\unicode{x2014}$essential for energy boosters in photon science and multistage facilities for compact high-energy particle colliders., Comment: 9 pages, 4 figures, 11 supplementary figures

Published

2024

3. The E302 instability-versus-efficiency experiment at FACET-II

Author

Finnerud, O. G., Lindstrøm, C. A., Chen, J. B. B., and Adli, E.

Subjects

Physics - Accelerator Physics

Abstract

We discuss plans for the E302 instability-efficiency experiment, starting in 2024 at the recently upgraded FACET-II facility at SLAC National Accelerator Laboratory. The beam-breakup instability will be the main area of study for the E302 experiment. With the imaging spectrometer at FACET-II, we introduce a novel technique for observing and quantifying the amplitude growth of the trailing bunch due to the transverse instability. Using the transverse position on the spectrometer screen and the transfer matrix of the magnetic lattice used for the spectrometer, we aim to extract a $x'$-$E$ charge distribution that can be used to quantify the amplitude of the beam. By varying the trailing bunch's charge and, hence, the beam loading of the accelerating field, we aim to adjust the wake-to-beam power transfer efficiency in the E302 experiment. We plan to quantify the amplitude for different configurations of the beam charge and, hence, investigate the relationship between the beam-breakup instability and efficiency. We use a combination of particle-in-cell (PIC) codes to simulate a beam-driven plasma wakefield accelerator from start-to-end with a FACET-II-like spectrometer and demonstrate the methodology that will be used for the instability studies at the E302 experiment., Comment: 9 pages, 9 figures, conference proceeding for the 6th European Advanced Accelerator Concepts workshop (EAAC2023), 17-23 September 2023

Published

2024

4. Status of and upgrade concepts for HALHF: the hybrid, asymmetric, linear Higgs factory

Author

Lindstrøm, C. A., D'Arcy, R., and Foster, B.

Subjects

Physics - Accelerator Physics, High Energy Physics - Experiment

Abstract

This contribution outlines the HALHF concept, which combines the high gradients achievable in plasma-wakefield acceleration with conventional radio-frequency acceleration. In HALHF, beam-driven plasma-wakefield cells are used to accelerate electrons to high energy. Because plasma-based acceleration of positrons is problematic, conventional RF acceleration is used but to much lower energy. The HALHF concept utilises not only asymmetric energies but also asymmetric bunch charges and asymmetric transverse emittances, leading to comparable luminosity to conventional facilities but much lower capital cost. Possible upgrades to the HALHF facility are discussed, in particular to the $\rm{t\bar{t}}$ threshold and to 550 GeV, where the Higgs self-coupling and $\rm{t\bar{t}}H$ coupling can be measured. Other upgrades include the provision of two interaction points, to implement a $\gamma$$\unicode{x2013}$$\gamma$ collider of two possible types and finally a symmetric high-energy collider if the problem of plasma-based positron acceleration can be solved., Comment: 13 pages, 4 figures, conference proceeding for the 6th European Advanced Accelerator Concepts workshop (EAAC2023), 17-23 September 2023

Published

2023

5. Positron Acceleration in Plasma Wakefields

Author

Cao, G. J., Lindstrøm, C. A., Adli, E., Corde, S., and Gessner, S.

Subjects

Physics - Accelerator Physics

Abstract

Plasma acceleration has emerged as a promising technology for future particle accelerators, particularly linear colliders. Significant progress has been made in recent decades toward high-efficiency and high-quality acceleration of electrons in plasmas. However, this progress does not generalize to acceleration of positrons, as plasmas are inherently charge asymmetric. Here, we present a comprehensive review of historical and current efforts to accelerate positrons using plasma wakefields. Proposed schemes that aim to increase the energy efficiency and beam quality are summarised and quantitatively compared. A dimensionless metric that scales with the luminosity-per-beam power is introduced, indicating that positron-acceleration schemes are currently below the ultimate requirement for colliders. The primary issue is electron motion; the high mobility of plasma electrons compared to plasma ions, which leads to non-uniform accelerating and focusing fields that degrade the beam quality of the positron bunch, particularly for high efficiency acceleration. Finally, we discuss possible mitigation strategies and directions for future research., Comment: 24 pages (30 pages with references), 22 figures

Published

2023

6. Energy Depletion and Re-Acceleration of Driver Electrons in a Plasma-Wakefield Accelerator

Author

Peña, F., Lindstrøm, C. A., Beinortaitė, J., Svensson, J. Björklund, Boulton, L., Diederichs, S., Foster, B., Garland, J. M., Caminal, P. González, Loisch, G., Schröder, S., Thévenet, M., Wesch, S., Wood, J. C., Osterhoff, J., and D'Arcy, R.

Subjects

Physics - Accelerator Physics, Physics - Plasma Physics

Abstract

For plasma-wakefield accelerators to fulfil their potential for cost effectiveness, it is essential that their energy-transfer efficiency be maximized. A key aspect of this efficiency is the near-complete transfer of energy, or depletion, from the driver electrons to the plasma wake. Achieving full depletion is limited by the process of re-acceleration, which occurs when the driver electrons decelerate to non-relativistic energies, slipping backwards into the accelerating phase of the wakefield and being subsequently re-accelerated. Such re-acceleration is unambiguously observed here for the first time. At this re-acceleration limit, we measure a beam driver depositing (57 $\pm$ 3)\% of its energy into a 195-mm-long plasma. Combining this driver-to-plasma efficiency with previously measured plasma-to-beam and expected wall-plug-to-driver efficiencies, our result suggests that plasma-wakefield accelerators can in principle reach or even exceed the energy-transfer efficiency of conventional accelerators., Comment: Manuscript: 7 pages, 4 figures; Supplementary material: 3 pages, 1 figure

Published

2023

7. Longitudinally resolved measurement of energy-transfer efficiency in a plasma-wakefield accelerator

Author

Boulton, L., Lindstrøm, C. A., Beinortaite, J., Svensson, J. Björklund, Garland, J. M., Caminal, P. González, Hidding, B., Loisch, G., Peña, F., Põder, K., Schröder, S., Wesch, S., Wood, J. C., Osterhoff, J., and D'Arcy, R.

Subjects

Physics - Accelerator Physics

Abstract

Energy-transfer efficiency is an important quantity in plasma-wakefield acceleration, especially for applications that demand high average power. Conventionally, the efficiency is measured using an electron spectrometer; an invasive method that provides an energy-transfer efficiency averaged over the full length of the plasma accelerator. Here, we experimentally demonstrate a novel diagnostic utilizing the excess light emitted by the plasma after a beam-plasma interaction, which yields noninvasive, longitudinally resolved measurements of the local energy-transfer efficiency from the wake to the accelerated bunch; here, as high as (58 $\pm$ 3)%. This method is suitable for online optimization of individual stages in a future multistage plasma accelerator, and enables experimental studies of the relation between efficiency and transverse instability in the acceleration process., Comment: 6 pages, 4 figures

Published

2022

8. Recovery time of a plasma-wakefield accelerator

Author

D'Arcy, R., Chappell, J., Beinortaite, J., Diederichs, S., Boyle, G., Foster, B., Garland, M. J., Caminal, P. Gonzalez, Lindstrøm, C. A., Loisch, G., Schreiber, S., Schröder, S., Shalloo, R. J., Thévenet, M., Wesch, S., Wing, M., and Osterhoff, J.

Subjects

Physics - Accelerator Physics

Abstract

The interaction of intense particle bunches with plasma can give rise to plasma wakes capable of sustaining gigavolt-per-metre electric fields, which are orders of magnitude higher than provided by state-of-the-art radio-frequency technology. Plasma wakefields can, therefore, strongly accelerate charged particles and offer the opportunity to reach higher particle energies with smaller and hence more widely available accelerator facilities. However, the luminosity and brilliance demands of high-energy physics and photon science require particle bunches to be accelerated at repetition rates of thousands or even millions per second, which are orders of magnitude higher than demonstrated with plasma-wakefield technology. Here we investigate the upper limit on repetition rates of beam-driven plasma accelerators by measuring the time it takes for the plasma to recover to its initial state after perturbation by a wakefield. The many-nanosecond-level recovery time measured establishes the in-principle attainability of megahertz rates of acceleration in plasmas. The experimental signatures of the perturbation are well described by simulations of a temporally evolving parabolic ion channel, transferring energy from the collapsing wake to the surrounding media. This result establishes that plasma-wakefield modules could be developed as feasible high-repetition-rate energy boosters at current and future particle-physics and photon-science facilities.

Published

2022

9. Progress of the FLASHForward X-2 high-beam-quality, high-efficiency plasma-accelerator experiment

Author

Lindstrøm, C. A., Beinortaite, J., Svensson, J. Björklund, Boulton, L., Chappell, J., Garland, J. M., Gonzalez, P., Loisch, G., Peña, F., Schaper, L., Schmidt, B., Schröder, S., Wesch, S., Wood, J., Osterhoff, J., and D'Arcy, R.

Subjects

Physics - Accelerator Physics, Physics - Plasma Physics

Abstract

FLASHForward is an experimental facility at DESY dedicated to beam-driven plasma-accelerator research. The X-2 experiment aims to demonstrate acceleration with simultaneous beam-quality preservation and high energy efficiency in a compact plasma stage. We report on the completed commissioning, first experimental results, ongoing research topics, as well as plans for future upgrades., Comment: 5 pages, 2 figures; proceeding of the EPS-HEP2021 conference (Hamburg, July 26-30 2021) submitted to Proceedings of Science

Published

2021

10. Overview of the Demonstration and Science Experiments (DSX) Mission

Author

Johnston, W. R., primary, Ginet, G. P., additional, Starks, M. J., additional, McCollough, J. P., additional, Sanchez, J. C., additional, Song, P., additional, Galkin, I. A., additional, Inan, U. S., additional, Lauben, D. S., additional, Tu, J., additional, Reinisch, B. W., additional, Linscott, I. R., additional, Roche, K., additional, Stelmash, S., additional, Allgeier, S., additional, Lambour, R., additional, Schoenberg, J., additional, Gillespie, W., additional, Farrell, W. M., additional, Xapsos, M. A., additional, Roddy, P. A., additional, Lindstrom, C. D., additional, Pedinotti, G. F., additional, Huston, S. L., additional, Albert, J. M., additional, Sinclair, A. J., additional, Davis, L. D., additional, Carilli, J. A., additional, Cooke, D. L., additional, and Parker, C. W., additional

Published

2023