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Кафедра квантовой электроники




Фамилия: Панов
Имя: Владимир
Отчество: Иванович
Ученая степень: доктор физ-мат. наук
Ученое звание: профессор
Комната: 411
Должность: заведующий кафедрой
Телефон: 939-11-04
Факс: 939-11-04
Email: panov@spmlab.phys.msu.su
Страница в интернете: http://spmlab.phys.msu.su/
Научные интересы: From 1986 - till the present time - work in the fields of scanning probe microscopy, spectroscopy and physics of nanostructures
1. The high-precision STM/STS, AFM and SNOM devices were constructed. Low temperature STM (LT STM) with special stage for sample cleaning by in situ cleavage was built. LT STM operates at low temperatures, ultrahigh vacuum and high magnetic fields. Multi-purpose SNOM for both scanning probe and scanning sample modes may be used at ten optical configurations (including polarization modes).
2. The mechanism of the tunneling in the nanometer size structures produced by clusters or thin polymeric Langmuir-Blodgett (LB) films was studied. Charge density waves (CDW) and induced conductivity of films were discovered.
3. A comparison of localized state density for SiO2--SiO:H and LB films of comb-like polymer -Si:H interfaces has been made by means of STM. The carrier mobility of the channel realised along the LB film was found to be 30 times greater then in that along the SiO2.
4. A procedure for controlled transfer and sedimentation of separate molecules has been elaborated. Conducting channels in such molecules were discovered and their properties were investigated by means of STM/STS. (1988- in List of publications No.22 )
5. The surface enhancement of non-linear-optical effects on monoatomic surface layers was studied by means of STM and reflected second harmonic (RSH) generation.
6. The method of spectroscopy within the framework of Atomic Force Microscopy was offered.
The limitation on the parameters of Yukawa long-range interaction was received from atomic-force microscopy experiment (testing of gravitational theories ).
7. The first observation by STM of the smallest carbon rods (tubelenes C36+12) having the diameter 0.8 nm on nanofilament films, prepared by vacuum electron beam graphite evaporation, has been made.
8. New dimensional quantization effects (DQE) in the vicinity of artificially produced clusters on semiconductor surface and near nanodefects on HOPG surface were observed by means of STM/STS. It was shown than the interaction between neighbouring defects can lead to DQ level splitting. The effects have local character and differ from “zero anomalies” often observed in tunnel junctions.
9. The influence of the Coulomb interaction of localized charges on scanning tunneling spectra of surface nanodefects was discovered and investigated. The shapes of tunneling spectra were explained taking into account finite relaxation time of nonequilibrium electrons and presence of localised states.
10. Light-induced conformational transformation of the naphthacenequinone (NQ) molecules is observed by scanning tunneling microscopy and spectroscopy. Additional sub-band of empty electronic states has been found for NQ molecules in A form and not found in B form. The conformational transformation is connected with the transfer of the phenoxy group from one oxygen to another.
11. The influence of resonant tunneling on the imaging of impurity atoms and defects on semiconductor surfaces was investigated by low temperature STM/STS. The anomalous effects of resonant tunneling channel switch on and off were observed. The effects were explained in the framework of nonequilibrium theoretical model of tunneling.
12. New nonequilibrium interaction effects of impurity atoms on semiconductor surface have been experimentally studied by means of STM/STS methods and theoretically analyzed using a self-consistent approach based on the Keldysh formalism.
13. Low-temperature method of identification of individual impurity atoms on a semiconductor surface by precision analyzing of local tunneling conductivity curves near impurities was developed. About 10 impurity atoms on and under A3B5 semiconductor surface were investigated and found out that each atom has its own tunneling conductivity spectra.
14. Magneto-optical effects, domain and domain walls were investigated by means of polarization near-field microscopy with spatial resolution up to 20 nm.
15. Effects of polarization contrast have been found in reflection SNOM experiments.
16. Coulomb singularity effects in tunneling spectroscopy of individual impurities were observed.
 

Основные публикации: 1. V. B. Braginskii and V. I. Panov
Verification of the eqivalence of inertial and gravitational mass. Sov. Phys. JETP, 34, 463 (1972)

2. V. B. Braginskii and V. I. Panov
The equivalence of inertial and gravitational mass. G.R.G. 3, №4, 404 (1972)

3. V. I. Panov and V.N. Rudenko
The detection of gravitation radiation impulses from superdens star-clasters. Doklady Akad.Nauk, 221, №3, 573 (1975)

4. I.I. Minakova, G.P.Minina, V.I.Panov, V.G.Petnikov
The oscillator stabilized by three-resonators system with superconducting resonator.
Izv. Vuzov SSSR-Radioelektronika XIX,№10,16 (1976)

5. V. B. Braginskii, I.I. Minakova, V. I. Panov
Prospects of creation of high-stable generators with narrow width of a line. Radiotechnika I Elektronika XXI(1), 192 (1976)

6. N.I.Balalikin, P.I. Zybietov, and V.I. Panov
Surface impedance of superconducting Nb films, Pisma v. Zh. Tekh. Fiz., 4, 407 (1978)

7. V. I. Panov and V.N. Frontov
The Cavendish experiment at large distances. Sov. Phys. JETP, 50, 852 (1979)

8. V. B. Braginskii, S.V. Vyatchanin, and V. I. Panov
Limiting stability of the frequency of self-excited oscillators. Sov. Phys. Dokl. 24(7),
562 (1979)

9. V. B. Braginsky and V. I. Panov
Superconducting resonators on sapphire. IEEE Trans.on Mag. Vol. MAG-15, №1, 30 (1979)

10. V.B. Braginskii, S.I.Vasil’ev, V.I.Panov
Investigation of thermal expansion of Al2O3 monocrystal at low temperatures. Sov. Tech. Phys. Lett. 6,665 (1980)

11. Kh.S. Bagdasarov, V. B. Braginsky, V. I. Panov and A.S. Timashov
High-quality dielectric ring resonators, Pisma v. Zh. Tekh. Fiz. 7, 10 (1981)

12. V. B. Braginskii, V.I.Panov, and V.D.Popel’nyuk
Detector of small mechanical vibrations for gravitational-wave antenna. Pisma v. Zn. Eksp. Teor. Fiz., 33(8), 423 (1981)

13. S.I.Vasil’ev, V.I.Panov
Sensitive dilatometer with capacitive transducer of displacement. Pribory Tekhnika Eksperimenta №2, 202 (1981)


14. V. I. Panov and V.N. Frontov
Torsion balance for measurement of small gravitational gradients. Pribory Tekhnika Eksperimenta №1, 253 (1981)

15. V. B. Braginsky, V. I. Panov, and A.S. Timashov
Abnormal low dissipation of electromagnetic waves in dielectric crystals. Doklady Akad. Nauk, 267(1), 74 (1982)

16. V.I. Panov and V.A. Khvostikov
Permittivity, molar volume and critical phenomena near the -point in liquid helium. Sov. Phys. JETP, 56, 99 (1982)

17. V. I. Panov and A.A. Sobyanin
Experimental study of the - transition in helium in narrow gaps. JETP Lett, 35,
№8, 404 (1982)

18. V.B. Braginsky, V.P. Mitrofanov, V.I. Panov
Systems with Small Dissipation, 1985, The University of Chicago Press, Chicago and London

19. S.I. Vasil’ev, V.B. Leonov and V.I.Panov
STM for investigation of structurally non-uniform surfaces. Sov. Tech. Phys. Lett. 13,391 (1987)

20. S.I. Vasil’ev, V.B. Leonov , V.I.Panov and S.V.Savinov
Scanning tunneling microscopy in air environment. Sov.Phys. Dokl. 32, 1002 (1987)

21. V.I. Panov
Scanning tunneling microscopy and surface spectroscopy. Sov. Phys.Usp.31(5), 471 (1988)

22. S.D.Alekperov, S.I.Vasiljev, A.A.Kononenko, E.P.Lukashev, V.I.Panov and
A.E.Semenov
Scanning tunneling microscopy of photosynthetic reaction center. Chemical Physics Letters 164, (2,3), 151 (1989) [ Doklady Akad. Nauk, 303(2), 341 (1988) ]

23. Yu.N. Moiseev, V.M.Mostepanenko,V.I.Panov, and I.Yu.Sokolov
Spectroscopy of inter-atomic interactions by means of Atomic Force Microscopy.
Sov. Tech. Phys. Lett. 15,789 (1988)

24. Yu.N. Moiseev, V.M.Mostepanenko,V.I.Panov, and I.Yu.Sokolov
Force dependences for the definition of the atomic force microscopy spatial resolution. Physics Letters A 132, 354 (1988)

25. O.A Aktsipetrov, S.I. Vasil’ev, V.I.Panov
Scanning tunnel microscopy of the surfaces of "cold" silver films and surface-enhanced second harmonic generation. Sov.Phys. JETP 67, 1010 (1988)

26. O.A Aktsipetrov, S.I. Vasil’ev, V.I.Panov
Role played by roughness in surface-enhanced Raman scattering in connection with scanning tunneling microscopy. JETP Lett. 47, 226 (1988)


27. V. I. Panov and A.A. Sobyanin
Finite-size effects in plane layers of liquid 4He near the -point. Physics Letters A127(2), 109 (1988)

28. N.S. Maslova and V.I. Panov
Scanning tunneling microscopy of atomic structure, electronic properties, and surface chemical reactions. Sov. Phys.Usp.32(1), 93 (1989)

29. Yu.N. Moiseev, V.M.Mostepanenko,V.I.Panov, and I.Yu.Sokolov
Limitation on the parameters of Yukawa long-range interaction from atomic-force microscopy. Sov. Phys. Dokl. 34,147 (1989)

30. S.D.Alekperov, S.I. Vasil’ev, V.B. Leonov , V.I.Panov and A.E.Semeonov
Study of asymmetric of the atomic image of the surface lattice of graphite by the STM method. Sov. Phys. Dokl. 34, 713 (1989)

31. O.A.Aktsipetrov, A.A.Nikulin, V.I.Panov, S.I.Vasil’ev
Surface enhanced second harmonic generation in cold deposited silver films and scanning tunneling microscopy. Solid State Commun. 73(6), 441 (1990 )

33. O.A.Aktsipetrov, A.A.Nikulin, V.I.Panov, S.I.Vasil’ev and A.V.Petukhov
Electromagnetic mechanism of surface enhanced second harmonic generation by”smooth” silver electrodes and scanning tunneling microscopy. Solid State Commun. 76(1), 55 (1990 )

34. Yu.N. Moiseev, V.M.Mostepanenko,V.I.Panov, and I.Yu.Sokolov
Experimental and theoretical research of forces and spatial resolution in Atomic Force Microscopy. Sov. Journ. Tech. Phys. 60(1), 141,(1990)

35. Yu. N. Moiseev, V.I. Panov, and G.I. Salistra
Nonuniformity of the dielectric permittivity and the density profile of adsorbed 4He films. Sov. Phys. JETP, 71,1101 (1990)

36. V.V.Kislov, I.E.Nevernov, and V.I.Panov
Scanning tunneling microscopy of monolayers of stearic acid on the surface of graphite. Sov. Phys. Dokl. 35, 944 (1990)

37. A.A.Kononenko, E.P.Lukashev, V.I.Panov, and E.A. Fedorov
Scanning Tunneling Microscopy of Functionally Active Membrane Fragments of Halobacteria containing Bacteriorodopsin. Doklady Biophysics. 313-315, 184(1990)

38. E.V.Blagov, Yu.N. Moiseev, V.M.Mostepanenko,V.I.Panov, and I.Yu.Sokolov
Diagnostic of boundary phase of HTS ceramics by method of atomic-force micriscipy. Pisma v. Zh. Tekh. Fiz. 17, 87(1991)

39. Yu.N. Moiseev, V.I.Panov, and S.V.Savinov
Influence of local friction on АFМ image of surface structure. Sov. Tech. Phys. Lett. 17(10), 24 (1991)





40. N.S. Maslova, Yu.N. Moiseev, V.I.Panov, S.V.Savinov, S.I.Vasil’ev, and I.V.Yaminskii
Tunneling through Adsorbate and Thin Films: Induced Conductivity, Charge Density Waves. Phys.Stat.Sol.(a) 131,35 (1992)

41. N.S. Maslova, Yu.N. Moiseev, V.I.Panov, S.V.Savinov, S.I.Vasil’ev, and D.A.Znamenskii
Atomic-force and scanning tunneling microscopy study of LB films of comb-shaped liquid-crystal polymer: molecular lattice, induced conductivity, and charge superstructure. Sov.Phys.JETP 75(3), 505 (1992)

42. V.A.Antonenko, P.A.Todua, D.A. Znamensky, Yu.N. Moiseev,and V.I.Panov
Electron properties of dielectric-semiconductor interfaces in SiO2 - -Si:H – Langmuir-Blodgett film structure. Solid State Commun. 81(3), 231 (1992 )

43. Yu.N. Moiseev, V.I.Panov, S.V.Savinov, S.I.Vasil’ev, and I.V.Yaminskii
AFM and STM activities at Advanced Technologies Center.Ultramicroscopy 42-44,1596 (1992)

44. L.A. Chernozatonskii, E.A. Fedorov, Z.Ja. Kosakovskaya, V.I.Panov, S.V.Savinov
STM evidence of smallest rod presence in nanofilament carbon structure. . Pisma v. Zn. Eksp. Teor. Fiz., 57,35 (1993)

45. E.V. Blagov, G.L. Klimchitskaya, V.M.Mostepanenko,V.I.Panov, and I.Yu.Sokolov
Diagnostics of radiation-induced point detects by atomic force microscopy. Tech. Phys. Lett. 19(4), 254 (1993)

46. V.M.Mostepanenko,V.I.Panov, and I.Yu.Sokolov
Broken continuity of the lines of constant force above a surface with a relief step and the resolution of atomic force microscope. Tech. Phys. Lett. 19(4), 251 (1993)

47. E.V. Blagov, G.L. Klimchitskaya, V.M.Mostepanenko,V.I.Panov, and I.Yu.Sokolov
Possible ways to determine the migration energy of point defects using atomic-force microscopy. Tech. Phys. Lett. 20(1), 34 (1994)

48. Yu.N. Moiseev, V.I.Panov, S.V.Savinov, and I.V.Yaminskii
Local probing instrumentation at Advanced Technologies Center: Surface and force devices with tunnelling sensor. J.Vac.Sci.Technol.B12(3), 1690 (1994)

49. N.S. Maslova, A.I. Oreshkin,V.I.Panov, S.V.Savinov
STM evidense of dimensional quantization on the nanometer size surface defects. Solid State Commun. 95(8), 507 (1995)

50. L.A. Chernozatonskii, Z.Ja. Kosakovskaya, E.A. Fedorov, V.I.Panov
New carbon tubelite-ordered film structure of multiplayer nanotubes. Physics Letters A197,40 (1995)

51. V. Dneprovskii, A.Eev, N.Gushina, D. Okorokov, V. Panov et al.
Strong Optical Nonlinearities in Quantum Wires and Dots of Porous Silicon. Phys.Stat.Sol.(b) 188,297 (1995)




52. O.A. Aktsipetrov, V.F. Dorfman, E.D. Mishina, T.V. Murzina, Yu.N. Moiseev, V.I. Panov
Second harmonic generation and scanning tunneling/atomic-force microscopy studies of tungsten-doped, amorphous-carbon films. Thin Solid Films 305,341 (1997)

53. P.I. Arseev, A. Depuydt, N. S. Maslova, V.I. Panov, S.V. Savinov
Problems of Low-Temperature STM Application to the High-Temperature Superconductors Investigation. Physics of low-dimensional structures. 5/6, 131 (1997)

54. V.V. Kolesov, V.I. Panov, and E.A. Fedorov
Production and STM/STS study of a tunnel nanostructure containing a single fullerene molecule. Journal of Commun. Technol.and Electronics 42(7), 818 (1997)

55. S.I.Vasil’ev, S.I. Oreshkin, S.V. Savinov, A. Depuydt, C. Van Haesendonck, and
V.I. Panov
Low-temperature scanning tunneling microscope for investigation in magnetic fields. Instrum. Exp. Tech. (USSR) 40,566 (1997)

56. Depuydt, N. S. Maslova, V. I.. Panov, V. V. Rakov, S.V. Savinov, and C. Van Haesendonck
Influence of resonant tunneling on the imaging of atomic defects on InAs(110) surfaces by low-temperature scanning tunneling microscopy. Appl. Phys. A 66, 171 (1998)

57. V.I. Panov, A.A. Ejov, V.V. Kolesov, and E.A. Fedorov
STM/STS study of thick fullerene films and STM fabricated nanostructure with single fullerene molecule. Molecular Materials, 10, 99, (1998)

58. A.I.Oreshkin, V.I. Panov, S.I.Vasil’ev, N.I. Koroteev, and S.A.Magnitskii
Direct STM observation of electron structure modification of naphtacenequinone molecules caused by photoisomerisation. JETP Lett. 68 (6), 521 (1998)

59. N. S. Maslova, S.I.Oreshkin, V.I. Panov, S.V. Savinov, A. Depuydt, and C. Van Haesendonck
Scanning tunneling spectroscopy of charge effects on semiconductor surfaces and atomic clusters. . JETP Lett. 67 (2), 146 (1998)

60. Depuydt, G.. Neuttiens, N. S. Maslova, S.I.Oreshkin, V.I. Panov, S.V. Savinov, and C. Van Haesendonck
Spatially resolved low temperature STS on AuFe spin glass films. Proceedings of 6th international symposium “Nanostructures”, June 22-26, St.Petersburg, Russia, p.111 (1998)

61. N. S. Maslova, V.I. Panov, S.V. Savinov, A. Depuydt, and C. Van Haesendonck
Surface charge structures interaction in low-temperature surface investigations. Phys. Low-Dim. Struct, 5/6, 169 (1999)

62. Depuydt, C. Van Haesendonck, N. S. Maslova, V. I.. Panov, S.V. Savinov, P.I. Arseev
Scanning tunneling microscopy and spectroscopy at low temperatures of the (110) surface of Te-doped GaAs single crystals. Phys.Rev. B 60(4), 2619 (1999)

63. A.V. Kartavykh, N. S. Maslova, V. I.. Panov, V. V. Rakov, S.V. Savinov
Tunneling spectroscopy of impurity atoms in a crystalline semiconductor matrix. Fiz. Tech.of Poluprovodnikov [Semiconductors] 34(4), 395 (2000)



64. P.I. Arseev, N. S. Maslova, S.I.Oreshkin, V.I. Panov, and S.V. Savinov
Scanning tunneling spectroscopy of nonequilibrium interacting impurity states on semiconductor surface. JETP Lett.72, 819 (2000)

65. N. S. Maslova, V.I. Panov, S.V. Savinov
Tunneling spectroscopy of the localized states of single impurity atoms on semiconductor surface. Physics-Uspekhi 170, №5, 575 (2000)

66. N. S. Maslova, A.I.Oreshkin, V.I. Panov, S.A. Magnitskii
Light-induced conformational transitions of individual molecules in ordered films. . Solid State Commun. 117, 41 (2001)

67. A.A. Ejov, D.A. Muzychenko,V.I.Panov
Local light polarization mapping and electromagnetic field imaging by SNOM. Proc. 8th Int. Symp. "Nanostructures: Physics and Technology" June 19 – 23, St. Peterburg, Russia, p.333 (2000)

68. N. S. Maslova, A.I.Oreshkin, S.I.Oreshkin, V.I. Panov, S.V. Savinov,and A.A. Kalachev
The influence of Coulomb interaction of localized charges on low-temperature scanning tunneling spectra of surface nanodefects. J.Phys.: Condens. Matter 13, 3941 (2001)

69. A.A. Ezhov, A.S. Logginov, D.A.Muzychenko, A.V. Nikolaev, and V.I. Panov
Scanning near field optical microscopy as a new tool for subwavelength-resolution magnetooptical investigations. The Physics of Metals and Metallography.92, N1, 277
(2001)

70. P.I. Arseev, N.S. Maslova, V.I. Panov, S.V. Savinov
Nonequilibrium tunneling effects of interacting Hubbard–Anderson impurities.
Experim. Theor. Phys., v. 94(1), 191 (2002)

71. P.I. Arseev, N.S. Maslova, V.I. Panov, S.V. Savinov
Coulomb singularity effects in the tunneling spectroscopy of individual impurities.
Experim. Theor. Phys. Lett. 76(5), 287 (2002)