Scientific Experience:

Theoretical nonlinear optics(1981-present):

Solvable models for spatial laser dynamics. Spatial solitons.

Superluminality and Self-focusing instabilities. Phase-locking of microchip laser arrays.

Theory of analog optical computing in microcavities.

Computational laser physics(1983-present):

Numerical modeling of microchip lasers and laser arrays for different cavity geometries.

Experimental laser physics(1979-1983):

Phase conjugation. Michelson interferometry. Statistical optics.
YAG MOPA laser systems.

Educational Experience:

Labs and Seminars in MIPT
Statistical Physics and Thermodynamics (Feb.2001 - June 2001)
Electromagnetism (Sept.2001 - Jan.2002)

Publications,patents
Programming:

Fortran,Java,JavaScript,HTML.

Matematika,MathCAD, Matlab, Maple.

Optical design software: Zemax, Lascad,GLAD.

Scientific Interests:
Quantum optics,path integrals,chaotic dynamics,superluminality,solitons,
quantum wells/dots,phase conjugation,stimulated scattering,microchip lasers,cold atoms.

Education:

Bsc, Msc from Moscow Institute of Physics and Technology - 1980.

Ph.D. in Laser Physics: P.N.Lebedev Physical Institute- 1994. Thesis:
"Periodic and chaotic spatial structures of radiation in nonlinear resonators and amplifiers".

Languages:

English : scientific - writing, technical - fluent, conversation - intermediate level.

Francais : reading.

Priority results:

Michelson interferometer with phase-conjugate mirrors(1980)
Prediction of the spatial solitons in self-imaging microcavity(1988)

Nonlocal maps for description of laser dynamics(1988)
Self-focusing instability suppression via Superluminal propagation(1988)
Scalable microchip solid-state laser arrays proposal(1990)
Theory of analog optical computing in microcavities(2003)
Professional memberships:
OSA(1995,2003), APS (1995), IEEE LEOS (complimentary membership-1997).

*Solvable models for spatial laser dynamics.*		*Spatial solitons.*
*Superluminality and Self-focusing instabilities.*		*Phase-locking of microchip laser arrays.*
*Theory of analog optical computing in microcavities.*

Quantum optics,path integrals,chaotic dynamics,superluminality,solitons, quantum wells/dots,phase conjugation,stimulated scattering,microchip lasers,cold atoms.

Quantum optics,path integrals,chaotic dynamics,superluminality,solitons,
quantum wells/dots,phase conjugation,stimulated scattering,microchip lasers,cold atoms.