Status of the inverse Compton backscattering source at Daresbury Laboratory

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• 作者：G. Priebe ; D. Filippetto ; O. Williams ; Y.M. Saveliev ; L.B. Jones ; D. Laundy ; M.A. MacDonald ; G.P. Diakun ; P.J. Phillips ; S.P. Jamison ; K.M. Spohr ; S. Ter-Avetisyan ; G.J. Hirst ; J. Collier ; E.A. Seddon
• 关键词：Energy-recovering linac ; ERL ; ERLP ; Accelerators and lasers in combined experiments ; ALICE ; Free-electron laser ; FEL ; Compton backscattering ; CBS ; Inverse compton scattering ; ICS ; Laser Compton scattering ; LCS ; Compton synchrotron radiation ; CSR ; Laser sy
• 刊名：Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment
• 出版年：2009
• 出版时间：1 September 2009
• 年：2009
• 卷：608
• 期：1, Supplement 1
• 页码：S109-S112
• 全文大小：496 K

文摘

Inverse Compton scattering is a promising method to implement a high-brightness, ultra-short, energy tuneable X-ray source at accelerator facilities and at laser facilities using laser wake-field acceleration. We have developed an inverse Compton X-ray source driven by the multi-10-TW laser installed at Daresbury Laboratory. Polarized X-ray pulses will be generated through the interaction of laser pulses with electron bunches delivered by the energy recovery linac commissioned at the ALICE facility with spectral peaks ranging from 0.4 to 12 Å, depending on the electron bunch energy and the scattering geometry. X-ray pulses containing up to 10⁷ photons per pulse will be created from head-on collisions, with a pulse duration comparable to the incoming electron bunch length. For transverse collisions the laser pulse transit time defines the X-ray pulse duration. The peak spectral brightness is predicted to be up to 10²¹ photon/(s mm² mrad² 0.1 % Δλ/λ). Called COBALD, this source will be initially used as a short-pulse diagnostic for the ALICE electron beam and will explore the extreme challenges of photon/electron beam synchronization, which is a fundamental requirement for all conventional accelerator and laser wake-field-acceleration-based sources.