Your search keyword '"Bettoni, S."' showing total 4 results

1. Machine learning based longitudinal virtual diagnostics at SwissFEL.

Author

Bettoni, S., Orlandi, G. L., Salomone, F., Boiger, R., Ischebeck, R., Xue, R., and Mostacci, A.

Subjects

*MACHINE learning, *FREE electron lasers, *SYNCHROTRON radiation, *PARTICLE beam bunching, *RADIO frequency, *RADIATION measurements

Abstract

The bunch length in a linac driven Free Electron Laser (FEL) is a major parameter to be characterized to optimize the final accelerator performance. In linear machines, this observable is typically determined from the beam imaged on a screen located downstream of a Transverse Deflecting Structure (TDS) used to impinge a time dependent kick along the longitudinal coordinate of the beam. This measurement is typically performed during the machine setup and only sporadically to check the beam duration, but it cannot be continuously repeated because it is time consuming and invasive. A non-invasive method to determine the electron bunch length has already been presented in the past. This method is based on the analysis of the synchrotron radiation light spot emitted by the bunch passing through a magnetic chicane, provided that the energy chirp impinged on the bunch by the upstream radio frequency structures is known. In order to overcome a systematic discrepancy affecting the synchrotron radiation monitor based results compared to the absolute TDS based ones, we implemented and optimized a machine learning approach to predict the bunch length downstream of the two SwissFEL compression stages—from about 10 fs up to about 2 ps—as well as the beam longitudinal profile at the first one. [ABSTRACT FROM AUTHOR]

Published

2024

2. Overview of SwissFEL dual-photocathode laser capabilities and perspectives for exotic FEL modes.

Author

Bettoni, S., Cavalieri, A., Dax, A., Divall, E., Hauri, C. P., Hunziker, S., Huppert, M., Kaiser, M., Paraliev, M., Sydlo, C., Vicario, C., and Trisorio, A.

Subjects

*FEMTOSECOND pulses, *FREE electron lasers, *FEMTOSECOND lasers, *LASERS, *HARD X-rays, *PARTICLE beam bunching, *SOFT X rays

Abstract

SwissFEL is a compact, high-brilliance, soft and hard X-ray free electron laser (FEL) facility that started user operation in 2019. The facility is composed of two parallel beam lines seeded by a common linear accelerator (LINAC), and a two-bunch photo-injector. For the injector, an innovative dual-photocathode laser scheme has been developed based on state-of-the-art ytterbium femtosecond laser systems. In this paper, we describe the performance of the SwissFEL photocathode drive lasers (PCDLs), the pulse-shaping capabilities as well as the versatility of the systems, which allow many different modes of operation of SwissFEL. The full control over the SwissFEL electron bunch properties via the unique architecture of the PCDLs will enable in the future the advent of more-advanced FEL modes; these modes include, but are not restricted to, the generation of single or trains of sub-femtosecond FEL pulses, multi-color FEL and finally, the generation of fully coherent X-ray pulses via laser-based seeding. [ABSTRACT FROM AUTHOR]

Published

2021

3. Outline of a dielectric laser acceleration experiment at SwissFEL.

Author

Prat, E., Bettoni, S., Calvi, M., Dehler, M., Frei, F., Hommelhoff, P., Kozak, M., McNeur, J., Loch, C. Ozkan, Reiche, S., Romann, A., and Ischebeck, R.

Subjects

*PARTICLE acceleration, *LASER beams, *FREE electron lasers, *MICROSTRUCTURE, *FEMTOSECOND pulses

Abstract

The Accelerator on a Chip International Program (ACHIP), funded by the Gordon and Betty Moore Foundation for a 5 year period, pursues basic research and development for a super-compact accelerator on a chip, where the accelerating structure is a dielectric microstructure excited by femtosecond laser pulses. The Paul Scherrer Institute (PSI) will contribute to this by providing the international collaboration access to the high-brightness electron beams in SwissFEL, where we plan to do a proof-of-principle demonstration of the acceleration of a highly relativistic beam. In this contribution we present the conceptual layout of the experiment, in which we will focus the beam down to sub-micrometer beam sizes. Start-to-end simulation results of the tracked electron beam, and first calculations of the accelerating field of the microstructure will be shown. [ABSTRACT FROM AUTHOR]

Published

2017

4. Generation and Characterization of Intense Ultralow-Emittance Electron Beams for Compact X-Ray Free-Electron Lasers.

Author

Prat, E., Dijkstal, P., Aiba, M., Bettoni, S., Craievich, P., Ferrari, E., Ischebeck, R., Löhl, F., Malyzhenkov, A., Orlandi, G. L., Reiche, S., and Schietinger, T.

Subjects

*FREE electron lasers, *X-ray lasers, *ELECTRON beams, *ELECTRON accelerators, *HARD X-rays, *LINEAR accelerators

Abstract

The transverse emittance of the electron beam is a fundamental parameter in linac-based x-ray free-electron lasers (FELs). We present results of emittance measurements carried out at SwissFEL, a compact x-ray FEL facility at the Paul Scherrer Institute in Switzerland, including a description of the novel high-resolution measurement techniques and the optimization procedure. We obtained slice emittance values at the undulator entrance down to 200 nm for an electron beam with a charge of 200 pC and an rms duration of 30-40 fs. Furthermore, we achieved slice emittances as low as 100 nm for 10 pC beams with few fs duration. These values set new standards for electron linear accelerators. The quality, verification, and control of our electron beams allowed us to generate high-power FEL radiation for a wavelength as short as 0.1 nm using an electron beam with an energy of only 6 GeV. The emittance values demonstrated at SwissFEL would allow producing hard x-ray FEL pulses with even lower-energy beams, thus paving the way for even more compact and cost-effective FEL facilities. [ABSTRACT FROM AUTHOR]

Published

2019