Theory and design studies for an rf-lin-ac-driven free-electron laser for the extreme UV

BRIAN D. McVEY; C. J. ELLIOTT; J. C. GOLDSTEIN; K. LEE; BRIAN E. NEWNAM; M. J. SCHMITT

International Quantum Electronics Conference
OSA Technical Digest (Optica Publishing Group, 1986),
paper WMM2

Theory and design studies for an rf-lin-ac-driven free-electron laser for the extreme UV

BRIAN D. McVEY, C. J. ELLIOTT, J. C. GOLDSTEIN, K. LEE, BRIAN E. NEWNAM, and M. J. SCHMITT

International Quantum Electronics Conference 1986

San Francisco, California United States
9–13 June 1986
ISBN: 0-936659-11-4

From the session
Physics of Free-Electron Lasers and Other New Light Sources: 1 (WMM)

Not Accessible

Your library or personal account may give you access

Get PDF
Email
Share
Get Citation
Copy Citation Text
B. D. McVEY, C. J. ELLIOTT, J. C. GOLDSTEIN, K. LEE, B. E. NEWNAM, and M. J. SCHMITT, "Theory and design studies for an rf-lin-ac-driven free-electron laser for the extreme UV," in International Quantum Electronics Conference, M. Richardson, C. Tang, D. Grischkowsky, and T. Hansch, eds., OSA Technical Digest (Optica Publishing Group, 1986), paper WMM2.

Export Citation
- BibTex
- Endnote (RIS)
- HTML
- Plain Text
Save article

Abstract

The theoretical design ot a free-electron laser (FEL) oscillator configuration operating in the extreme UV spectral region (1000-100 Å) is described. The FEL is assumed to be driven by an electron beam from an rf linear accelerator. Since the small signal gain decreases with optical wavelength, and high gains (~4) are required due to lower mirror reflectivity, the major emphasis on our design studies is to determine the electron- beam quality necessary for operation. The measure of electron-beam quality are values for the current, the transverse emittance, and energy spread. Initial simulation results indicate that an electron beam with the following parameters is required: / ≥ 100A; ε_n (normalized emittance) ≤ 20π; and Δγ/γ ≤ 0,25%, The present FEL experiment at Los Alamos has exceeded the required current with ~3-4 times larger values for the normalized emittance and energy spread.¹ Improvements in the emittance and energy spread are expected with development of the photocathode injector.²

PDF Article

More Like This

Progress toward an rf-linac free-electron laser for the extreme UV spectral region

BRIAN E. NEWNAM, BRIAN D. MCVEY, J. C. GOLDSTEIN, C. J. ELLIOTT, M. J. SCHMITT, K. LEE, T. S. WANG, B. CARLSTEN, J. S. FRASER, R. L. SHEFFIELD, M. L. SCOTT, and P. N. ARENDT
WMM3 International Quantum Electronics Conference (IQEC) 1986

Progress Toward an RF-Linac Free-Electron Laser for the Extreme-Ultraviolet Spectral Region*

B. E. Newnam, B. D. McVey, J. C. Goldstein, C. J. Elliott, M. J. Schmitt, K. Lee, T. S. Wang, B. E. Carlsten, J. S. Fraser, R. L. Sheffield, M. L. Scott, and P. N. Arendt
MA3 Short Wavelength Coherent Radiation: Generation and Applications (HFSW) 1986

Advances in free-electron laser theory

W. B. COLSON
THMM1 International Quantum Electronics Conference (IQEC) 1986

Previous Article Next Article