Abstract
The microbunching instability is known to be detrimental to x-ray free electron laser performance. At the Linear Coherent Light Source, the microbunching instability is suppressed with a laser heater, which increases the uncorrelated energy spread of e-beam in the injector. While the current system has been shown to improve x-ray brightness, other laser architectures could further enhance performance. In this study, we model the interaction between a laser and e-beam with arbitrary transverse profiles and examine the effect of various laser designs on the energy distribution of the electrons after the injector and laser heater, as well as their ability to suppress microbunching instability. This simulation incorporates random transverse jitter in order to reproduce physically representative operation of the Linac Coherent Light Source. We compare Gaussian and Laguerre-Gaussian modes, and explore composite beams in the form of an array of Gaussian beamlets. We conclude that the Gaussian laser profile is highly susceptible to e-beam ellipticity and random transverse jitter. The Laguerre-Gaussian profile, a mathematically ideal solution to suppressing microbunching, is less susceptible to these effects and can provide effective suppression even with a distorted e-beam, though performance can be improved by increasing stabilization. The array of beamlets presents a solution that produces consistent and smooth energy distributions with significantly less variance in heating than the Laguerre-Gaussian profile.
Highlights
We examine the effect of random transverse jitter and elliptical e-beam profiles on energy distributions induced by the current laser heater (LH) to resemble routine beam operation at Linac Coherent Light Source (LCLS)
We explore alternative LH designs that outperform state-of-the-art LH architectures under these considerations based on either Laguerre-Gaussian 01 (LG01) beams or a Gaussian beamlet array (BA)
By using a computational model that simulates the interaction between arbitrary transverse laser and e-beam distributions, we examine various methods to generate Gaussian-like e-beam energy distributions
Summary
Free electron lasers (FEL) are the brightest hard x-ray photon sources in the world, producing femtosecond pulses of photos with wavelengths as low as 1 Å [1,2,3,4,5,6]. We examine the effect of random transverse jitter and elliptical e-beam profiles on energy distributions induced by the current LH to resemble routine beam operation at LCLS. By using a computational model that simulates the interaction between arbitrary transverse laser and e-beam distributions, we examine various methods to generate Gaussian-like e-beam energy distributions. This is because MBI is suppressed more when this distribution is more Gaussian due to more effective Landau damping [11,17]. We conclude that Gaussian beams have practical limitations due to beam overlap and alignment instabilities compared to either a LG01-mode laser distribution with enhanced stabilization or a discretized array of beamlets
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