1 / 23

NUMERICAL SIMULATION OF NONLINEAR EFFECTS IN VOLUME FREE ELECTRON LASER (VFEL)

NUMERICAL SIMULATION OF NONLINEAR EFFECTS IN VOLUME FREE ELECTRON LASER (VFEL). K. Batrakov, S. Sytova Research Institute for Nuclear Problems, Belarusian State University. Free Electron Laser. FEL lasing is aroused by different types of spontaneous radiation:

atalo
Download Presentation

NUMERICAL SIMULATION OF NONLINEAR EFFECTS IN VOLUME FREE ELECTRON LASER (VFEL)

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. NUMERICAL SIMULATION OF NONLINEAR EFFECTS IN VOLUME FREE ELECTRON LASER (VFEL) K. Batrakov, S. Sytova Research Institute for Nuclear Problems, Belarusian State University

  2. Free Electron Laser FEL lasing is aroused by different types of spontaneous radiation: undulator radiation, Smith-Purcell or Cherenkov radiation and so on. Using positive feedback in FELs reduces the working length and provides oscillation regime of generation. This feedback is usually one-dimensional and can be formed either by two parallel mirrors or by one-dimensional diffraction grating, in which incident and diffracted waves move along the electron beam. Theoretical investigations show that it is one of the effective schemes with n-wave volume distributed feedback (VDFB)

  3. What is volume distributed feedback ? one-dimensional distributed feedback two-dimensional distributed feedback Volume (non-one-dimensional) multi-wave distributed feedback is the distinctive feature of Volume Free Electron Laser (VFEL)

  4. Benefits provided bythe volume distributed feedback The new law of instability for an electron beam passing through a spatially-periodic medium provides the increment of instability in degeneration points proportional to 1/(3+s) , here s is the number of surplus waves appearing due to diffraction. This increment differs from the conventional increment for single-wave system (TWTA and FEL), which is proportional to 1/3. (V.G.Baryshevsky, I.D.Feranchuk, Phys.Lett. 102A (1984) 141) This new law provides for noticeable reduction of electron beam current density (108 A/cm2 for LiH crystal against 1013 A/cm2 required in G.Kurizki, M.Strauss, I.Oreg, N.Rostoker, Phys.Rev. A35 (1987) 3427) necessary for achievement the generation threshold. In X-ray range this generation threshold can be reached for the induced parametric X-ray radiation in crystals, i.e. to create X-ray laser (V.G.Baryshevsky, K.G.Batrakov, I.Ya. Dubovskaya, J.Phys D24 (1991) 1250) This law is universal and valid for all wavelength ranges regardless the spontaneous radiation mechanism

  5. What is Volume Free Electron Laser ? * volume diffraction grating volume diffraction grating volume “grid” resonator X-ray VFEL * Eurasian Patent no. 004665

  6. Use of volume distributed feedback makes available: • frequency tuning at fixed energy of electron beam in significantly wider range than conventional systems can provide • more effective interaction of electron beam and electromagnetic wave allows significant reduction of threshold current of electron beam and, as a result, miniaturization of generator • reduction of limits for available output power by the use of wide electron beams and diffraction gratings of large volumes • simultaneous generation at several frequencies

  7. VFEL experimental history 1996 Experimental modeling of electrodynamic processes in the volume diffraction grating made from dielectric threads V.G.Baryshevsky,K.G.Batrakov, I.Ya. Dubovskaya, V.A.Karpovich, V.M.Rodionova, NIM 393A (1997) 71 2001 First lasing of volume free electron laser in mm-wavelength range. Demonstration of validity of VFEL principles. Demonstration of possibility for frequency tuning at constant electron energy V.G.Baryshevsky, K.G.Batrakov,A.A.Gurinovich, I.I.Ilienko, A.S.Lobko, V.I.Moroz, P.F.Sofronov, V.I.Stolyarsky,NIM 483 A (2002) 21 2004 New VFEL prototype with volume “grid” resonator.

  8. side view diffraction gratings top view Resonator (2001) The interaction of the exciting diffraction grating with the electron beam arouses Smith-Purcell radiation. The second resonant grating provides distributed feedback of generated radiation with electron beam by Bragg dynamical diffraction.

  9. New VFEL generator (2004) • Main features: • volume gratings (volume “grid”) • electron beam of large cross-section • electron beam energy 180-250 keV • possibility of gratings rotation • operation frequency 10 GHz • tungsten threads with diameter 100 m First observation of generation in the backward wave oscillator with a "grid" diffraction grating and lasing of the volume FEL with a "grid" volume resonator* ( V. Baryshevsky et al., LANL e-print archive: physics/0409125)

  10. Electrodynamical properties of a "grid" volume resonator * Electrodynamical properties of a volume resonator that is formed by a periodic structure built from the metallic threads inside a rectangular waveguide depend on diffraction conditions. Then in this system the effect of anomalous transmission for electromagnetic waves could appear similarly to the Bormann effect well-known in the dynamical diffraction theory of X-rays. Resonant grating provides VDFB of generated radiation with electron beam * V. Baryshevsky, A. Gurinovich, LANL e-print archive: physics/0409107

  11. “Grid” volume resonator* V.G.Baryshevsky, N.A.Belous, A.Gurinovich et al.,Abstracts of FEL06, (2006), TUPPH012

  12. VFEL in Bragg geometry t u k kt L 0

  13. u t Laue geometry

  14. k1 u k k2 0 L Three-wave VFEL, Bragg-Bragg geometry

  15. Equations for electron beam

  16. Main equations

  17. System for two-wave VFEL: System parameters The integral form of current is obtained by averaging over two initial phases: entrance time of electron in interaction zone and transverse coordinate of entrance point in interaction zone. In the mean field approximation double integration over two initial phases can be reduced to single integration. - detuning from exact Cherenkov condition γjare direction cosines, χ±1are Fourier components of the dielectric susceptibility of the target

  18. Code VOLC - VFEL simulation

  19. j j L δ χ β li βi Results of numerical simulation (2002-2006): Laue- Laue VFEL Three-wave Some cases of bifurcation points SASE Two-wave Amplification regime Bragg Generation regime Laue Amplification regime Generation regime Synchronism of several modes: 1, 2, 3 SASE Bragg- Bragg Amplification regime Generation threshold Generation threshold Generation regime with external mirrors Bragg- Laue Generation regime with external mirrors

  20. Dependence of the threshold current on assymetry factor of VDFB 3 0 0 2 7 0 with absorption without absorption 2 4 0 2 1 0 1 8 0 This relation confirms that VDFB allows to control threshold current. 1 5 0 j,A/cm2 1 2 0 9 0 6 0 3 0 0 - 2 0 - 1 8 - 1 6 - 1 4 - 1 2 - 1 0 - 8 - 6 - 4 - 2 b

  21. 1 E + 5 For n modes in synchronism*: 1 E + 4 1 E + 3 1 E + 2 | E | 1 0 1 t w o - w a v e g e o m e t ry, one mode in synchronism 2 - r o o t d e g e n e r a t i o n p o i n t 0 . 1 i n t h r e e - w a v e g e o m e t r y 3 - r o o t d e g e n e r a t i o n p o i n t 0 . 0 1 1 0 1 5 2 0 2 5 3 0 3 5 4 0 4 5 5 0 5 5 6 0 6 5 7 0 m L , c Current threshold for two- and three-wave geometry in dependence on L So, threshold current can be significantly decreased when modes are degenerated in multiwave diffraction geometry *V.Baryshevsky, K.Batrakov, I.Dubovskaya, NIM 358A (1995) 493

  22. References (VFEL theory and experiment) • V.G.Baryshevsky, I.D.Feranchuk, Phys.Lett. 102A (1984) 141-144 • V.G.Baryshevsky, Doklady Akademii Nauk USSR 299 (1988) 19 • V.G.Baryshevsky, K.G.Batrakov, I.Ya. Dubovskaya, Journ.Phys D24 (1991) 1250-1257 • V.G.Baryshevsky, NIM 445A (2000) 281-283 • Belarus Patentno. 20010235 (09.10.2001) • Russian Patent no. 2001126186/20 (04.10.2001) • Eurasian Patent no. 004665 (25.09.2001) • V.G.Baryshevsky et al., NIM A 483 (2002) 21-24 • V.G.Baryshevsky et al., NIM A 507 (2003) 137-140 • V. Baryshevsky et al., LANL e-print archive:physics/ 0409107, physics/0409125, physics/0605122, physics/0608068 • V.G.Baryshevsky et al.,Abstracts of FEL06, (2006), TUPPH012, TUPPH013

  23. References (VFEL simulation) • Batrakov K., Sytova S.Mathematical Modelling and Analysis,9 (2004) 1-8. • Batrakov K., Sytova S. Computational Mathematics and Mathematical Physics 45: 4 (2005) 666–676 • Batrakov K., Sytova S.Mathematical Modelling and Analysis. 10: 1 (2005) 1–8 • Batrakov K., Sytova S. Nonlinear Phenomena in Complex Systems,8 : 4(2005) 359-365 • Batrakov K., Sytova S. Nonlinear Phenomena in Complex Systems,8 : 1(2005) 42–48 • Batrakov K., Sytova S. Mathematical Modelling and Analysis. 11: 1 (2006) 13–22 • Batrakov K., Sytova S. Abstracts of FEL06, (2006),MOPPH005

More Related