Physical Review Accelerators and Beams (Jun 2020)

Polarization control of a free-electron laser oscillator using helical undulators of opposite helicities

  • Jun Yan,
  • Hao Hao,
  • Senlin Huang,
  • Jingyi Li,
  • Vladimir N. Litvinenko,
  • Peifan Liu,
  • Stepan F. Mikhailov,
  • Victor G. Popov,
  • Gary Swift,
  • Nikolay A. Vinokurov,
  • Ying K. Wu

DOI
https://doi.org/10.1103/PhysRevAccelBeams.23.060702
Journal volume & issue
Vol. 23, no. 6
p. 060702

Abstract

Read online Read online

Polarized photon beams provide a unique experimental tool for the study of various polarization-dependent physical processes. Here, we report the experimental demonstration of full polarization control of an oscillator free-electron laser (FEL) using helical undulators of opposite helicities. Using two helical undulator magnets of opposite helicities and a buncher magnet in between, we have generated a linearly polarized FEL beam with any desirable polarization direction. With the development of a high-precision FEL polarimeter, we are able to optimize the highly polarized FEL beams in visible wavelengths and measure the polarization with high accuracy, demonstrating linear polarization P_{lin}>0.99 on the routine basis and with the maximum polarization reaching P_{lin}=0.998. In this paper, we describe the FEL configuration, experimental setup, and related beam diagnostics, including the newly developed high-precision FEL polarimeter. We report our experimental approaches to generate, tune up, and characterize the polarization controllable FEL beams and share a new insight into how high-degree polarization is realized based upon our investigation of the temporal structure of the FEL beam. This FEL polarization control technique has been used successfully to generate a polarization controllable Compton γ-ray beam for nuclear physics experiments.