Your search keyword '"G. Penco"' showing total 5 results

1. Addendum: Experimental evidence of intrabeam scattering in a free-electron laser driver (2020 New J. Phys. 22 083053)

Author

S Di Mitri, G Perosa, A Brynes, I Setija, S Spampinati, P H Williams, A Wolski, E Allaria, S Brussaard, L Giannessi, G Penco, P R Rebernik, and M Trov

Subjects

General Physics and Astronomy

Abstract

A conceptual inaccuracy in the calculation of energy spread induced by intrabeam scattering in the presence of linear acceleration is put in evidence. A new self-consistent equation is presented. Two new solutions are provided in the approximation of Coulomb logarithm independent of the particle energy, and for a weak energy dependence. A comparison of the three solutions is shown; it does not imply any noticeable modification to the previously published data, hence the published conclusions remain valid.

Published

2022

2. Addendum: Beyond the limits of 1D coherent synchrotron radiation (2018 New J. Phys. 20 073035)

Author

A D Brynes, P Smorenburg, I Akkermans, E Allaria, L Badano, S Brussaard, M Danailov, A Demidovich, G De Ninno, D Gauthier, G Gaio, S B van der Geer, L Giannessi, M J de Loos, N S Mirian, G Penco, P Rebernik, F Rossi, I Setija, S Spampinati, C Spezzani, M Trovò, P H Williams, and S Di Mitri

Subjects

accelerators, beam instabilities, free-electron lasers, Science, Physics, QC1-999

Abstract

This paper is an addendum to reference (Brynes et al 2018 New J. Phys. 20 073035), in which we studied the transverse emittance growth due to coherent synchrotron radiation (CSR) in the bunch compressor of a free-electron laser. Analytic results based on the theory of CSR were compared with results from experiment and simulation. Recent results have been published (Stupakov 2019 arXiv: 1901.10745 ) which correct the theoretical emittance growth, predicting a smaller increase than that which was expected based on previous results. When comparing these new calculations with the emittance growth that was measured experimentally, and with 3D simulations, we find an improved agreement when the bunch compression approaches its maximum value.

Published

2021

3. Experimental evidence of intrabeam scattering in a free-electron laser driver

Author

S Di Mitri, G Perosa, A Brynes, I Setija, S Spampinati, P H Williams, A Wolski, E Allaria, S Brussaard, L Giannessi, G Penco, P R Rebernik, and M Trovò

Subjects

intrabeam scattering, microbunching, free electron laser, Science, Physics, QC1-999

Abstract

The effect of multiple small-angle Coulomb scattering, or intrabeam scattering (IBS) is routinely observed in electron storage rings over the typical damping time scale of milliseconds. So far, IBS has not been observed in single pass electron accelerators because charge density orders of magnitude higher than in storage rings would be needed. We show that such density is now available at high brightness electron linacs for free-electron lasers (FELs). We report measurements of the beam energy spread in the FERMI linac in the presence of the microbunching instability, which are consistent with a revisited IBS model for single pass systems. We also show that neglecting the hereby demonstrated effect of IBS in the parameter range typical of seeded VUV and soft x-ray FELs, results in too conservative a facility design, or failure to realise the accessible potential performance. As an example, an optimization of the FERMI parameters driven by an experimentally benchmarked model, opens the door to the extension of stable single spectral line emission to the water window (2.3–4.4 nm), with far-reaching implications for experiments in a variety of disciplines, ranging from physics and chemistry to biology and material sciences, and including nonlinear x-ray optics based on the four-wave-mixing approach.

Published

2020

4. Beyond the limits of 1D coherent synchrotron radiation

Author

A D Brynes, P Smorenburg, I Akkermans, E Allaria, L Badano, S Brussaard, M Danailov, A Demidovich, G De Ninno, D Gauthier, G Gaio, S B van der Geer, L Giannessi, M J de Loos, N S Mirian, G Penco, P Rebernik, F Rossi, I Setija, S Spampinati, C Spezzani, M Trovò, P H Williams, and S Di Mitri

Subjects

coherent synchrotron radiation, free electron lasers, accelerators, Science, Physics, QC1-999

Abstract

An understanding of collective effects is of fundamental importance for the design and optimisation of the performance of modern accelerators. In particular, the design of an accelerator with strict requirements on the beam quality, such as a free electron laser (FEL), is highly dependent on a correspondence between simulation, theory and experiments in order to correctly account for the effect of coherent synchrotron radiation (CSR), and other collective effects. A traditional approach in accelerator simulation codes is to utilise an analytic one-dimensional approximation to the CSR force. We present an extension of the 1D CSR theory in order to correctly account for the CSR force at the entrance and exit of a bending magnet. A limited range of applicability to this solution—in particular, in bunches with a large transverse spot size or offset from the nominal axis—is recognised. More recently developed codes calculate the CSR effect in dispersive regions directly from the Liénard–Wiechert potentials, albeit with approximations to improve the computational time. A new module of the General Particle Tracer code was developed for simulating the effects of CSR, and benchmarked against other codes. We experimentally demonstrate departure from the commonly used 1D CSR theory for more extreme bunch length compression scenarios at the FERMI FEL facility. Better agreement is found between experimental data and the codes which account for the transverse extent of the bunch, particularly in more extreme compression scenarios.

Published

2018

5. Tunability experiments at the FERMI@Elettra free-electron laser

Author

E Allaria, A Battistoni, F Bencivenga, R Borghes, C Callegari, F Capotondi, D Castronovo, P Cinquegrana, D Cocco, M Coreno, P Craievich, R Cucini, F D'Amico, M B Danailov, A Demidovich, G De Ninno, A Di Cicco, S Di Fonzo, M Di Fraia, S Di Mitri, B Diviacco, W M Fawley, E Ferrari, A Filipponi, L Froehlich, A Gessini, E Giangrisostomi, L Giannessi, D Giuressi, C Grazioli, R Gunnella, R Ivanov, B Mahieu, N Mahne, C Masciovecchio, I P Nikolov, G Passos, E Pedersoli, G Penco, E Principi, L Raimondi, R Sergo, P Sigalotti, C Spezzani, C Svetina, M Trovò, and M Zangrando

Subjects

Science, Physics, QC1-999

Abstract

FERMI@Elettra is a free electron-laser (FEL)-based user facility that, after two years of commissioning, started preliminary users' dedicated runs in 2011. At variance with other FEL user facilities, FERMI@Elettra has been designed to deliver improved spectral stability and longitudinal coherence. The adopted scheme, which uses an external laser to initiate the FEL process, has been demonstrated to be capable of generating FEL pulses close to the Fourier transform limit. We report on the first instance of FEL wavelength tuning, both in a narrow and in a large spectral range (fine- and coarse-tuning). We also report on two different experiments that have been performed exploiting such FEL tuning. We used fine-tuning to scan across the 1s–4p resonance in He atoms, at ≈23.74 eV (52.2 nm), detecting both UV–visible fluorescence (4p–2s, 400 nm) and EUV fluorescence (4p–1s, 52.2 nm). We used coarse-tuning to scan the M _4,5 absorption edge of Ge (∼29.5 eV) in the wavelength region 30–60 nm, measured in transmission geometry with a thermopile positioned on the rear side of a Ge thin foil.

Published

2012