• M.-E. Couprie, M. LABAT
  CEA/DSM/DRECAM/SPAM, Gif-sur-Yvette
• B. Carre, D. Garzella, G. Lambert
  CEA/Saclay, Gif-sur-Yvette
• O.V. Chubar, A. Loulergue, L. Nahon
  SOLEIL, Gif-sur-Yvette
• M. Jablonka, F. Meot, A. Mosnier
  CEA/DSM/DAPNIA, Gif-sur-Yvette
• J.-R. Marques
  LULI, Palaiseaux
• P. Monot
  CEA/DSM, Gif-sur-Yvette
• J.-M. Ortega
  LURE, Orsay
• A. Rousse
  LOA, Palaiseau

ARC-EN-CIEL (Accelerator-Radiation for Enhanced Coherent Intense Extended Light), the French project of a fourth generation light source aims at providing the user community with coherent femtosecond light pulses covering from UV to soft X ray. It is based on a CW 1 GeV superconducting linear accelerator delivering high charge, subpicosecond, low emittance electron bunches with a high repetition rate. The FEL is based on in the injection of High Harmonics in Gases in a High Gain Harmonic Generation scheme, leading to a rather compact solution. The produced radiation extending down to 0.8 nm with the Non Linear Harmonic reproduces the good longitudinal and transverse coherence of the harmonics in gas. Optional beam loops are foreseen to increase the beam current or the energy. They will accommodate fs synchrotron radiation sources in the IR, VUV and X ray ranges and a FEL oscillator in the 10 nm range. An important synergy is expected between accelerator and laser communities. Indeed, electron plasma acceleration will be tested for possible future compact electron beam sources for Xray FEL. Fs hard X ray can also be produced by Thomson Scattering. An overview of the user scientific case will also be given.

• G.P. Williams, S.V. Benson, G.H. Biallas, D. Douglas, J.G. Gubeli, G. Neil, M.D. Shinn, S. Zhang
  Jefferson Lab, Newport News, Virginia
• O.V. Chubar, P. D. Dumas
  SOLEIL, Gif-sur-Yvette

Funding: This work supported by the US Army Night Vision Lab, ONR, JTO, the Commonwealth of Virginia, the Air Force Research Laboratory, and DOE Contract DE-AC05-84ER40150. We thank Fred Dylla for his expert advice and encouragement.

Short bunches of electrons in the Jefferson Lab FEL emit multiparticle coherent edge radiation as they enter the dipole prior to the outcoupler mirror. This light is more collimated than synchrotron light and furthermore is modified by interference from the last chicane magnet after the high reflector. This light provides an additional heat load on the outcoupler in a wavelength range it was not designed to handle. We have performed calculations of this effect using a new extension of the Synchrotron Radiation Workshop code which, importantly, takes into account both acceleration and velocity (or Coulomb) terms of the emitted electric field. We have also measured THz properties of some of the mirrors. We show how the addition of a decompression chicane mitigates these problems.