- lasers and their applications for cutting materials and biotissue;
- fiber-optic sensors and variations of the mode composition of propagating laser radiation in waveguide structures of various profiles;
- some issues of microelectronics,
- microvibration, micromechanics;
- problems of ecology and air pollution;
- intensification of precipitation from natural clouds, and in particular acoustic methods of deposition of various aerosols.
Biography
Ph.D. Tamara Tulaykova.
Tulaykova Tamara Viktorovna was born in Moscow, Russia. She graduated Moscow Institute of Physics and Technology (www.mipt.ru) in 1977 on a specialty ‘automatics and electronics’. In 1978-1996 worked at Prokhoriov’s General Physics Institute of Russian Academy of Sciences (RAS) (http://www.gpi.ru/eng/index.php) where she received the Ph.D. Degree in 1985 in the area of physical devices. She work later in the Institute of Geosphere Dynamics (http://idg3.chph.ras.ru/index.php?lang=en ) of Russian Academy of Sciences and at Institute of mechanics of RAS (http://www.ipmnet.ru/en/). She is retired now, her last position was a leading scientific researcher.
Her science abilities are lasers, optics, fiber optics, micro mechanics, sensors, atmospheric processes, precipitation enhancement, climate. She is an author of 140 published papers, 10 patents and 5 monographs.
Under her scientific guidance the series of students and Ph.D. students performed their dissertation works. She developed and presented the course of lectures titled ‘The introduction course for the special function for Ph.D students in physics’ for students at Moscow Institute of Physics and Technology (www.mipt.ru).
She was a leader or member in series of projects for the Russian Fund for Fundamental Research in mentioned themes, also in Industrial projects. The industry projects have themes: development of devises for transmission of high-power laser irradiation into optical cables (in 1988-1990); fiber-optical sensors to measure the gas or liquid admixtures (in 1994-1996 for Gas industry).
Last 15 years she developed new methods for the climate recovery to reduce global warming effects; these methods are based on atmospheric CO2 purification, precipitation enhancement and cloud management, method to save Arctic/Antarctic ice, etc .
Main publications:
Tamara Tulaikova, Svetlana Amirova, Introduction course for the special functions, Business-book, M., 2009, 165 pp.
T.Tulaikova, A.Michtchenko, S.Amirova, Acoustic rains, Physmathbook, M., 2010, 143 pp.
S. G. Lukishova, N. R. Minuey Mendez, T. V. Tulaĭkova, “Investigation of a soft aperture formed by photooxidation of a rare-earth impurity in fluorite and used as an intracavity component in a YAG : Er<sup>3+</sup> laser”, Kvantovaya Elektronika, 21:2 (1994), 126–128 [Quantum Electron., 24:2 (1994), 117–119]
B. G. Panchev, V. A. Sychugov, T. V. Tulaĭkova, “SIMPLE METHOD OF LINK-UP OF FIBER LIGHT-GUIDES WITH PLANAR WAVE-GUIDE IN
DEVICES OF SPECTRAL THICKENING OF COMMUNICATION CHANNELS”, Zhurnal Tekhnicheskoi Fiziki, 58:9 (1988), 1786–1788
3.
I. A. Avrutskiĭ, V. I. Baryshev, V. P. Duraev, E. T. Nedelin, A. S. Svakhin, V. A. Sychugov, T. V. Tulaĭkova, V. I. Shveĭkin, V. V. Shishkov, “Radiation sources for fiber-optic communication lines with wavelength-division multiplexing of data channels in the range 1.3–1.6 μm”, Kvantovaya Elektronika, 15:4 (1988), 702–704 [Sov J Quantum Electron, 18:4 (1988), 446–448]
1986
4.
M. I. Belovolov, E. M. Dianov, A. V. Kuznetsov, V. Kh. Pencheva, V. A. Sychugov, T. V. Tulaĭkova, “Ordinary generator-gauge of narrow lines of single-frequency laser generation”, Pisma v Zhurnal Tekhnicheskoi Fiziki, 12:21 (1986), 1316–1320
5.
A. S. Svakhin, V. A. Sychugov, T. V. Tulaĭkova, “Dispersive device on polished cladding of a single-mode fiber waveguide”, Kvantovaya Elektronika, 13:2 (1986), 440–442 [Sov J Quantum Electron, 16:2 (1986), 291–293]
1984
6.
V. A. Sychugov, A. V. Tishchenko, T. V. Tulaĭkova, “NARROW-BAND INTEGRAL-OPTICAL FILTERS”, Zhurnal Tekhnicheskoi Fiziki, 54:8 (1984), 1555–1558
7.
A. M. Prokhorov, V. A. Sychugov, T. V. Tulaĭkova, “Âëèÿíèå æèäêîãî âîëíîâîäà íà ïðîöåññ îáðàçîâàíèÿ ðåøåòîê
ïðè ôîòîòðàâëåíèè ïîëóïðîâîäíèêîâ”, Fizika i Tekhnika Poluprovodnikov, 18:12 (1984), 2125–2129
8.
P. V. Bazakutsa, V. A. Sychugov, A. V. Tishchenko, T. V. Tulaĭkova, “NEW ASPECT ON SURFACE MICRORELIEF AS A RESULT OF STIMULATION OF GUIDING
WAVES”, Pisma v Zhurnal Tekhnicheskoi Fiziki, 10:8 (1984), 491–495
9.
M. Miler, V. A. Sychugov, T. V. Tulaĭkova, “Multichannel demultiplexer for optical communication lines”, Kvantovaya Elektronika, 11:3 (1984), 597–601 [Sov J Quantum Electron, 14:3 (1984), 404–406]
10.
V. A. Sychugov, T. V. Tulaĭkova, “Waveguide effect during photoetching of semiconductors”, Kvantovaya Elektronika, 11:3 (1984), 437–438 [Sov J Quantum Electron, 14:3 (1984), 301–302]
V. A. Sychugov, A. S. Svakhin, T. V. Tulaĭkova, “STUDY OF SPECTRAL AND ABERRATION CHARACTERISTICS OF THICKENING AND
THINNING AGENTS OF OPTICAL CONNECTION CHANNELS BASED ON PLANAR
WAVEGUIDES”, Zhurnal Tekhnicheskoi Fiziki, 53:12 (1983), 2387–2393
1982
12.
M. I. Belovolov, E. M. Dianov, A. A. Kuznetsov, A. S. Svakhin, V. A. Sychugov, T. V. Tulaĭkova, “Spectral demultiplexer with a plate waveguide”, Kvantovaya Elektronika, 9:2 (1982), 429–432 [Sov J Quantum Electron, 12:2 (1982), 252–254]
A. S. Svakhin, V. A. Sychugov, T. V. Tulaĭkova, “Method for the fabrication of high-efficiency small-period diffraction gratings”, Kvantovaya Elektronika, 8:10 (1981), 2254–2256 [Sov J Quantum Electron, 11:10 (1981), 1377–1379]
14.
E. M. Dianov, A. A. Kuznetsov, V. A. Sychugov, T. V. Tulaĭkova, “Spectral channel demultiplexer utilizing a planar multimode waveguide”, Kvantovaya Elektronika, 8:2 (1981), 384–386 [Sov J Quantum Electron, 11:2 (1981), 229–231]
1980
15.
V. A. Sychugov, T. V. Tulaĭkova, “Method for preparing photoresist grating masks. Part II”, Kvantovaya Elektronika, 7:8 (1980), 1785–1789 [Sov J Quantum Electron, 10:8 (1980), 1029–1031]
16.
S. S. Stepanov, V. A. Sychugov, T. V. Tulaĭkova, “Method for preparing photoresist grating masks”, Kvantovaya Elektronika, 7:4 (1980), 849–854 [Sov J Quantum Electron, 10:4 (1980), 483–486]