M. Emamian
Duke University
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Publication
Featured researches published by M. Emamian.
Proceedings Particle Accelerator Conference | 1995
Vladimir N. Litvinenko; Y. Wu; B. Burnham; John M. J. Madey; F. Carter; C. Dickey; M. Emamian; J. Gustavsson; N. Hower; P. Morcombe; S.H. Park; P.G. O'Shea; R. Sachtshale; D. Straub; G. Swift; P. Wang; J. Widgren
The commissioning of the 1 GeV Duke Storage Ring began in November, 1994 with the demonstration of injection, storage and ramping to 1 GeV at the first attempt. The ring is now operational. The Duke project is unique in that the storage ring and linac were designed, constructed and commissioned by a small new University laboratory, operating on a low budget. The team is comprised of six accelerator physicists and graduate students, eight engineers, and fifteen technicians.
Nuclear Instruments & Methods in Physics Research Section A-accelerators Spectrometers Detectors and Associated Equipment | 2001
I.V. Pinayev; Vladimir N. Litvinenko; Seong Hee Park; Y. Wu; M. Emamian; N. Hower; Janet Patterson; G. Swift
Abstract We use the gain modulation technique to generate giant pulses in the OK-4/Duke storage ring FEL for applications requiring high peak power. This technique provides the increase of the peak power by several orders of magnitude. It is also very reliable, predictable and reproducible. The design, the parameters and the gain modulator performance are described. Comparison of expected and measured pulse forms is presented. Application of gain modulator for future harmonic generation experiments is also discussed.
ieee particle accelerator conference | 2007
S.F. Mikhailov; M. Busch; M. Emamian; S. Hartman; Yujong Kim; Jian Li; V. Popov; G. Swift; P. Wallace; P. Wang; Y. Wu; C.R. Howell; N.G. Gavrilov; G.Ya. Kurkin; Yu. Matveev; Oleg Anchugov; D. Shvedov; N.A. Vinokurov
A booster synchrotron (Duke booster) has been built and recently commissioned at Duke University Free Electron Laser Laboratory (DFELL) as part of the High Intensity Gamma-ray Source (HIGS) facility upgrade. HIGS is collaboration between the DFELL and Triangle Universities Nuclear Laboratory (TUNL). The booster provides top-off injection into the Duke FEL storage ring in the energy range of 0.24 -1.2 GeV. When operating the Duke storage ring to produce high energy Compton gamma ray beams above 20 MeV, continuous electron beam loss occurs. The lost electrons are replenished by the booster injector operating in the top-off mode. The present operational injection and extraction rate of the machine allows us to routinely replenish up to 5-108 electrons per second. The compactness of the booster posed a challenge for its development and commissioning. The booster has been successfully commissioned in 2006. This paper reports experience of commissioning and initial operation of the booster.
Free-Electron Laser Challenges | 1997
Vladimir N. Litvinenko; Y. Wu; B. Burnham; Seong Hee Park; M. Emamian; J. Faircloth; S. Goetz; N. Hower; John M. J. Madey; J. Meyer; P. Morcombe; O. Oakeley; Jennifer Patterson; R. Sachtschale; G. Swift; P. Wang; I.V. Pinayev; M.G. Fedotov; N.G. Gavrilov; V.M. Popik; V.N. Repkov; L.G. Isaeva; G.N. Kulipanov; G. Y. Kurkin; S. F. Mikhailov; A.N. Skrinsky; Nikolai A. Vinokurov; P.D. Vobly; Eduard Zinin; Alex H. Lumpkin
The OK-4/Duke storage ring FEL was commissioned in November 1996 and demonstrated lasing in the near UV and visible ranges (345 - 413 nm). The OK-4 is the first storage ring FEL with the shortest wavelength and highest power for UV FELs operating in the United States. During one month of operation we have performed preliminary measurements of the main parameters of the OK-4 FEL: its gain, lasing power and temporal structure. In addition to lasing, the OK-4/Duke FEL generated a nearly monochromatic (1% FWHM) 12.2 MeV gamma-ray beam. In this paper we describe the design and initial performance of the OK-4/Duke storage ring FEL. We compare our predictions with lasing results. Our attempt to lase in the deep UV range (around 193 nm) is discussed. The OK-4 diagnostic systems and performance of its optical cavity are briefly described.
bipolar/bicmos circuits and technology meeting | 2003
S.F. Mikhailov; Vladimir N. Litvinenko; M. Busch; M. Emamian; S. Hartman; I.V. Pinayev; V. Popov; G. Swift; P. Wallace; Y. Wu; N.G. Gavrilov; Yu. Matveev; D. Shvedov; N.A. Vinokurov; P.D. Vobly
In this paper we present current status of the Booster Synchrotron for the Duke FEL storage ring. The Booster which is recently under design, fabrication and construction, will provide full energy injection into the storage ring at energy from 0.3 to 1.2 GeV. The Duke storage ring FEL (SR FEL) operates in lasing mode with 193-700 nm wavelength range. The geometry of the Duke SR FEL provides for interacting head-on collision of e-beam and FEL photons. This mode of operation is used to generate intense beams of /spl gamma/-rays from 2 MeV to about 200 MeV (currently from 2 MeV to 58 MeV). Generation of /spl gamma/-rays with energy exceeding 20 MeV causes the loss of electrons, which will be replaced by injection from the Booster operating in a top-off mode. The paper presents design and status for elements of magnetic system and vacuum system, as well as design and parameters of fast extraction kicker with 11 nS pulse duration. All these element are designed and will be fabricated by Budker Institute of Nuclear Physics, Novosibirsk, Russia.
The eighth beam instrumentation workshop | 1998
I.V. Pinayev; M. Emamian; Vladimir N. Litvinenko; S.H. Park; Y. Wu
The control system of an optical cavity is described. Usage of the piezoelectric actuators and position sensitive photodetectors in this system allows us to reach a resolution at a submicroradian level and to suppress mirror vibrations below 50 Hz.
Proceedings of the 1999 Particle Accelerator Conference (Cat. No.99CH36366) | 1999
I.V. Pinayev; G. Detweiler; M. Emamian; N. Hower; M. Johnson; Vladimir N. Litvinenko; O. Oakley; Se-Hwan Park; J. Patterson; G. Swift; Y. Wu
The Duke storage ring is a facility dedicated for the deep UV free electron laser (FEL) development. It is especially designed for high peak power applications, having a long optical cavity and large energy acceptance. In this paper we describe a FEL gain modulator and optical cavity control system, which are essential for obtaining maximal peak power.
PACS2001. Proceedings of the 2001 Particle Accelerator Conference (Cat. No.01CH37268) | 2001
I.V. Pinayev; M. Emamian; J. Gustavsson; Vladimir N. Litvinenko; P. Morcombe; O. Oakeley; V. Rathbone; G. Swift; P. Wang; Glenn S. Edwards
Current status of Mark III free electron laser and its upgrades are presented.
Proceedings of the 1997 Particle Accelerator Conference (Cat. No.97CH36167) | 1997
Vladimir N. Litvinenko; Y. Wu; B. Burnham; S.H. Park; M. Emamian; J. Faircloth; S. Goetz; N. Hower; John M. J. Madey; J. Meyer; P. Morcombe; O. Oakeley; J. Patterson; R. Sachtschale; G. Swift; P. Wang; I.V. Pinayev; M.G. Fedotov; N.G. Gavrilov; V.M. Popik; V.N. Repkov; L.G. Isaeva; G.N. Kulipanov; G.Ya. Kurkin; S.F. Mikhailov; A.N. Skrinsky; N.A. Vinokurov; P.D. Vobly; Eduard Zinin; A. H. Lumpkin
The OK-4 is the first storage ring FEL operating in the United States. It was commissioned in November, 1996 and demonstrated lasing in the near UV and visible ranges (345-413 nm) with extracted power of 0.15 W. In addition to lasing, the OK-4/Duke FEL generated a nearly monochromatic (1% FWHM) /spl gamma/-ray beam. In this paper we describe the initial performance of the OK-4/Duke storage ring FEL and /spl gamma/-ray source.
Proceedings of the 2005 Particle Accelerator Conference | 2005
M. Emamian; M. Busch; S. Mikhailov; N. Gavrilov
This paper presents the methodology and initial results for mechanical alignment of the booster synchrotron for the Duke Free Electron laser Laboratory (FELL) storage ring. The booster is a compact design and requires special considerations for alignment. All magnets and vacuum chambers in the arcs have been designed such that a laser tracker can be best utilized for alignment. A parametric 3D design package has been used to determine target coordinates. These target coordinates evolve from design goals to physically verified dimensions by modifying the parametric model to match mechanical measurement data after fabrication. By utilizing the functionality of a laser tracker system [1] and a parametric 3D modeler, a direct and efficient measurement and alignment technique has been developed for the booster ring’s complex geometry.
