Backward and forward quasi- phase matched multiwave SRS in nonlinear periodical structures Victor G. Bespalov, Russian Research Center "S. I. Vavilov State.

Slides:

Advertisements

Similar presentations

Key CLARITY technologies II – Four-Wave Mixing wavelength conversion National and Kapodistrian University of Athens Department of Informatics and Telecommunications.

Advertisements

Femtosecond lasers István Robel

Classical behaviour of CW Optical Parametric Oscillators T. Coudreau Laboratoire Kastler Brossel, UMR CNRS 8552 et Université Pierre et Marie Curie, PARIS,

Backward and forward multiwave stimulated Raman scattering Victor G. Bespalov, Russian Research Center "S. I. Vavilov State Optical Institute" Nikolai.

Multi-wave Mixing In this lecture a selection of phenomena based on the mixing of two or more waves to produce a new wave with a different frequency, direction.

The efficient generation of anti- Stokes radiation at multiwave forward and backward stimulated Raman scattering Victor G. Bespalov, Russian Research Center.

Simultaneously Stokes and anti-Stokes Raman amplification in silica fiber Victor G. Bespalov Russian Research Center "S. I. Vavilov State Optical Institute"

Multiwave stimulated Raman scattering with quasi-phase matching Victor G. Bespalov Russian Research Center "S. I. Vavilov State Optical Institute" Nikolai.

Fundamentals of Photonics

ANTI-STOKES STIMULATED RAMAN SCATTERING IN PHOTONIC CRYSTALS Nikolay S. Makarov, SPbSU ITMO/MSU, MT Victor G. Bespalov, S.I. Vavilov State Optical Institute.

S Digital Communication Systems Fiber-optic Communications - Supplementary.

Stimulated scattering is a fascinating process which requires a strong coupling between light and vibrational and rotational modes, concentrations of different.

A New Design Tool for Nanoplasmonic Solar Cells using 3D Full Wave Optical Simulation with 1D Device Transport Models Liming Ji* and Vasundara V. Varadan.

The split operator numerical solution of Maxwell’s equations Q. Su Intense Laser Physics Theory Unit Illinois State University LPHY 2000Bordeaux FranceJuly.

Quasi-phase matching SRS generation. Nikolai S. Makarov, State Institute of Fine Mechanics and Optics, Victor G. Bespalov, Russian Research Center "S.

Combined Stokes-anti-Stokes Raman amplification in fiber Victor G. Bespalov All Russian Research Center "S. I. Vavilov State Optical Institute" Nikolai.

Present status of the laser system for KAGRA Univ. of Tokyo Mio Lab. Photon Science Center SUZUKI, Ken-ichiro.

Laser physics simulation program Lionel Canioni University Bordeaux I France.

Gilad Marcus, Arie Zigler and Lazar Friedland

Optical Engineering for the 21st Century: Microscopic Simulation of Quantum Cascade Lasers M.F. Pereira Theory of Semiconductor Materials and Optics Materials.

Positronium Rydberg excitation in AEGIS Physics with many positrons International Fermi School July 2009 – Varenna, Italy The experimental work on.

Fundamentals of Photonics 1 NONLINEAR OPTICS- III.

Quasi-phase matching transient SRS generation Victor G. Bespalov Russian Research Center "S. I. Vavilov State Optical Institute" Nikolai S. Makarov Saint-Petersburg.

Janez Žabkar Advisers: dr. Marko Zgonik dr. Marko Marinček

Dr. Jie ZouPHY Chapter 18 Superposition and Standing Waves.

EE 230: Optical Fiber Communication Lecture 6 From the movie Warriors of the Net Nonlinear Processes in Optical Fibers.

Narrow transitions induced by broad band pulses  |g> |f> Loss of spectral resolution.

Fiber-Optic Communications James N. Downing. Chapter 2 Principles of Optics.

INTRO TO SPECTROSCOPIC METHODS (Chapter 6) NATURE OF LIGHT AND INTERACTION WITH MATTER Electromagnetic Radiation (i.e., “light”) –Wave-particle duality.

Stimulated Raman scattering If high enough powered radiation is incident on the molecule, stimulated Anti-Stokes radiation can be generated. The occurrence.

Driven autoresonant three-oscillator interactions Oded Yaakobi 1,2 Lazar Friedland 2 Zohar Henis 1 1 Soreq Research Center, Yavne, Israel. 2 The Hebrew.

Jacob B Khurgin Johns Hopkins University, Baltimore Greg Sun

All-Fiber Optical Parametric Oscillator (FOPO) Chengao Wang.

Nonlinear Optics: Phenomena, Materials and Devices -Honors senior undergraduate and graduate level course. -Approximately lecture hours + 3 seminars.

Milti-wave interaction in metamaterials

Quasi-phase matching anti-Stokes SRS generation Victor G. Bespalov All Russian Research Center "S. I. Vavilov State Optical Institute" Nikolai S. Makarov.

Chapter 8. Second-Harmonic Generation and Parametric Oscillation

Picosecond fiber laser for thin film micro-processing

High power ultrafast fiber amplifiers Yoann Zaouter, E. Cormier CELIA, UMR 5107 CNRS - Université de Bordeaux 1, France Stephane Gueguen, C. Hönninger,

Masters Course: Experimental Techniques Detection of molecular species (with lasers) Techniques Direct absorption techniques Cavity Ring Down Cavity Enhanced.

A. Komarov 1,2, F. Amrani 2, A. Dmitriev 3, K. Komarov 1, D. Meshcheriakov 1,3, F. Sanchez 2 1 Institute of Automation and Electrometry, Russian Academy.

Intra-cavity Pulse Shaping of Mode-locked Oscillators Shai Yefet, Naaman Amer and Avi Pe’er Department of physics and BINA Center of nano-technology, Bar-Ilan.

Suppression of a Parasitic Pump Side-Scattering in Backward Raman Amplifiers of Laser Pulses in Plasmas A.A. Solodov, V. M. Malkin, N. J. Fisch.

Shaping Pulses Before They are Born Avi Pe’er Physics Department and BINA center for nano-technology, Bar Ilan University FRISNO 11 Shai Yefet, Naaman.

Interaction of laser pulses with atoms and molecules and spectroscopic applications.

Observation of ultrafast nonlinear response due to coherent coupling between light and confined excitons in a ZnO crystalline film Ashida Lab. Subaru Saeki.

Institute of Atomic and Molecular Sciences, Academia Sinica, Taiwan National Taiwan University, Taiwan National Central University, Taiwan National Chung.

1 Superluminal Light Pulses, Subluminal Information Transmission Dan Gauthier and Michael Stenner * Duke University, Department of Physics, Fitzpatrick.

Nonlinear Optics in Plasmas. What is relativistic self-guiding? Ponderomotive self-channeling resulting from expulsion of electrons on axis Relativistic.

Sample : GaAs (8nm) / Al 0.3 Ga 0.7 As (10nm) ×20 multiple quantum wells Light source : Mode-locked femtosecond Ti-sapphire laser Detection : Balancing.

Relativistic nonlinear optics in laser-plasma interaction Institute of Atomic and Molecular Sciences Academia Sinica, Taiwan National Central University,

Optical Amplifiers By: Ryan Galloway.

Quasi-phase matched anti-Stokes stimulated Raman scattering; Saint-Petersburg, 6 – 9 June 2003 Makarov N.S., V.G.,

Generation of Spurious Signals in Nonlinear Frequency Conversion Tyler Brewer, Russell Barbour, Zeb Barber.

Highly efficient Raman fiber laser Collaborators: E. Bélanger M. Bernier B. Déry D. Faucher Réal Vallée.

Ch 10 Pages ; Lecture 24 – Introduction to Spectroscopy.

The influence of backward Stokes on quasi-phase matched multiwave SRS in nonlinear periodical structures Victor G. Bespalov, Russian Research Center "S.

Michael Scalora U.S. Army Research, Development, and Engineering Center Redstone Arsenal, Alabama, & Universita' di Roma "La Sapienza" Dipartimento.

February 2-4, 2004ONDM 04, Ghent, Belgium1 All-optical gain-controlled lumped Raman fibre amplifier Miroslav Karásek Jiří Kaňka Pavel Honzátko Jan Radil.

Improved Distributed - Loss Gyro-TWA Yi Sheng Yeh, Chi-Wen Su, Yu-Tsung Lo, Ting-Shu Wu, Department of Electrical Engineering, Southern Taiwan University.

§8.4 SHG Inside the Laser Resonator

1 Opto-Acoustic Imaging 台大電機系李百祺. 2 Conventional Ultrasonic Imaging Spatial resolution is mainly determined by frequency. Fabrication of high frequency.

Four wave mixing in submicron waveguides

31 outline particles, waves, and light

Quasi-phase matching anti-Stokes SRS generation

Polarization in spectral lines

Multiwave quasi-phase matching stimulated Raman scattering with dispersion of Raman gain Nikolai S. Makarov Saint-Petersburg State Institute of Fine Mechanics.

Fiber Laser Part 1.

9 Nonlinear Optics.

Optical-phase conjugation in difference-frequency generation

Presentation transcript:

Backward and forward quasi- phase matched multiwave SRS in nonlinear periodical structures Victor G. Bespalov, Russian Research Center "S. I. Vavilov State Optical Institute" Nikolai S. Makarov, Saint-Petersburg State Institute of Fine Mechanics and Optics (Technical University)

Outline Principle of quasi-phase matching System of multiwave SRS equations Numerical simulations results Conclusions References Backward and forward quasi-phase matched multiwave SRS in nonlinear periodical structures; Saint-Petersburg, 30 June – 2 July 2003 Makarov N.S., V.G.,

Principle of quasi-phase matching Raman active medium Nonlinearity  (2) Nonlinearity  (3) H2H2 H2H2 H2H2 H2H2  (3)  0  (3) =0 z I 2w LкLк d 31 c-axis LкLк Backward and forward quasi-phase matched multiwave SRS in nonlinear periodical structures; Saint-Petersburg, 30 June – 2 July 2003 Makarov N.S., V.G.,

Principle of quasi-phase matching at SRS Generalized phase on active layers input do not practically change, that in a final result provides a realization of quasi- phase matching conditions , rad  (3)  0  (3) =0 Backward and forward quasi-phase matched multiwave SRS in nonlinear periodical structures; Saint-Petersburg, 30 June – 2 July 2003 Makarov N.S., V.G.,

System of forward and backward multiwawe SRS equations  j i – wave mismatching, g j ± – steady-state Raman gain coefficient,  j – frequencies of interacting waves, E j ± – complex wave amplitudes Backward and forward quasi-phase matched multiwave SRS in nonlinear periodical structures; Saint-Petersburg, 30 June – 2 July 2003 Makarov N.S., V.G.,

Model verification: waves profiles at different input pump intensities (left – input pump and right – output pump) t, ns I, GW/cm 2 Backward and forward quasi-phase matched multiwave SRS in nonlinear periodical structures; Saint-Petersburg, 30 June – 2 July 2003 Makarov N.S., V.G.,

Model verification: waves profiles at different input pump intensities (left – output forward Stokes and right – output backward Stokes) t, ns I, GW/cm 2 Backward and forward quasi-phase matched multiwave SRS in nonlinear periodical structures; Saint-Petersburg, 30 June – 2 July 2003 Makarov N.S., V.G.,

Barium nitrate Hydrogen Raman gain dispersion Backward and forward quasi-phase matched multiwave SRS in nonlinear periodical structures; Saint-Petersburg, 30 June – 2 July 2003 Makarov N.S., V.G.,

Influence of high SRS components on calculations precision For best calculation accuracy it is necessary to take into account at least the generation of 3 Stokes and 3 anti-Stokes SRS components Backward and forward quasi-phase matched multiwave SRS in nonlinear periodical structures; Saint-Petersburg, 30 June – 2 July 2003 Makarov N.S., V.G.,

The influence of backward SRS on QPM realization (active layers length) Backward and forward quasi-phase matched multiwave SRS in nonlinear periodical structures; Saint-Petersburg, 30 June – 2 July 2003 Makarov N.S., V.G.,

The influence of backward SRS on QPM realization (passive layers length) Backward and forward quasi-phase matched multiwave SRS in nonlinear periodical structures; Saint-Petersburg, 30 June – 2 July 2003 Makarov N.S., V.G.,

Conclusions Our model of forward and backward multiwave SRS is quality and quantity compared with experimental results For best accuracy of QPM SRS simulations it is necessary to take into account the dispersion of Raman gain coefficient For studying of multiwave SRS influence on QPM structure realization it is necessary to take into account the generation at least of 3 Stokes and 3 anti-Stokes SRS components The influence of backward SRS on QPM structure realization results in the small difference between layers length of optimal QPM structure and small decreasing of resulting anti-Stokes conversion efficiency (~25% at backward and forward SRS, ~30% at forward SRS) The oscillations of optimal layers length are partially connected with backward SRS influence and with insufficient precision of layers length determination due to high computational complexity of this task Backward and forward quasi-phase matched multiwave SRS in nonlinear periodical structures; Saint-Petersburg, 30 June – 2 July 2003 Makarov N.S., V.G.,

References Armstrong J.A., Bloembergen N., Ducuing J., Pershan P.S. // Phys. Rev., 1962, 127, pp Bespalov V.G., Makarov N.S. Quasi-phase matching generation of blue coherent radiation at stimulated Raman scattering // Optics Communications 2002, 203 (3-6), pp Maier M., Kaiser W., Giordmaine J.A. Backward stimulated Raman scattering // Phys. Rev., 1969, V. 177, №2, pp Raijun Chu, Morton Kanefsky, Joel Falk Numerical study of transient stimulated Brillouin scattering // J. Appl. Phys., 1992, V. 71, №10, pp Zaporozhchenko R.G., Kilin S.Ya, Bespalov V.G., Stasel’ko D.I. Formation of the spectra of backward stimulated Raman scattering from the quantum noise of polarization of a scattering medium // Opt.&Spectr., 1999, V. 86, №4, pp Bischel W.K., Dyer M.J. Wavelength dependence of the absolute Raman gain coefficient for the Q(1) transmission in H2 // J. Opt. Soc. Am. B, 1985, V. 3, pp Backward and forward quasi-phase matched multiwave SRS in nonlinear periodical structures; Saint-Petersburg, 30 June – 2 July 2003 Makarov N.S., V.G.,