PUBLISHED WORKS
Books:
1. Yu.
Dahnovsky, T. Leggett, Yu. Ovchnnikov, M. Semenov, Directed dissipative tunneling, Nauka, Moscow, 2011.
2. Yu.I. Dahnovsky, V.D. Krevchik, V.Ya.
Krivnov, M.B. Semenov, and K. Yamamoto, 2005, Transfer Processes in
Low-Dimensional Systems (UT Research Institute Press, Tokyo), pp. 680.
3. Yu. Dahnovsky, V. D. Krevchik,
A. A. Ovchinnikov, M. B. Semenov, and A. K. Agringazin, 2003, The principles of driven modulation of
low-dimensional structures, UNC DO (a
publishing company at Moscow State University), Moscow, 500 pp.
4. (Textbook, 571 pages) Yu. Dahnovsky, A. A. Ovchinnikov, V. Ch. Zhukovsky, M. B. Semenov,
A. I. Ternov, V. D. Krevchik,
A. K. Agringazin, 2003. Introduction to modern
mesoscopic phenomena, Penza State
University Publishing, Penza .
Journal Articles:
1.
V. Proshchenko and Yu.
Dahnovsky, Optical Spectra of Nano-Ferro- and Antiferro-Magnets,
Phys. Chem. Chem. Phys. 17, 26828
(2015).
2.
V. Proshchenko and Yu.
Dahnovsky, Magnetic effects in Mn-doped CdSe nanocrystals, Phys. Status Solidi B 252, 2275 2279 (2015).
3.
A. Pimachev and Yu.
Dahnovsky, Optical and Magnetic Properties of PbS
Nanocrystals Doped by Manganese Impurities, J. Phys. Chem. C 119, 16941 1946 (2015).
4.
V. Proshchenko and Yu.
Dahnovsky, Optical Spectra of Nano-Ferro- and Antiferro-Magnets,
Phys. Chem. Chem. Phys. 17, 26828
(2015).
5.
V. Proshchenko and Yu. Dahnovsky, Transition metal doped
semiconductor quantum dots: Tunable emission, in: Photoinduced
Processes at Surfaces and in nanomaterials, Ed. D. Kilin, ACS Symposium Series, ACS, ,
Washington DC) Ch. 5, p. 118 (2015).
6.
A. Pimachev and Yu.
Dahnovsky, Electronic structure calculations of PbS
quantum rods and tubes, J. Appl. Phys. 115,
043705 (2014).
7.
V. Proshchenko and Yu. Dahnovsky, Mn
impurity concentration dependence of optical spectra in Cdn-xMnxSen
od various shapes and sizes, Chem. Phys. Lett. 595-596,
250-255, (2014).
8.
V. Proshchenko and Yu. Dahnovsky, Tunable luminescence in Cdn-xMnxSen
quantum dots: Theoretical study, J. Phys. Chem. C 118, 28314–28321 (2014).
9.
V. Proshchenko and and Yu. Dahnovsky,
Size-dependent density of states and optical spectra of CdSE
quantum rods and tubes, Chem. Phys. Lett. 595-596, 250-255 (2014).
10. V. Proshchenko and and Yu. Dahnovsky, Spectroscopic and
electronic structure properties of CdSe nanocrystals:
spheres and cubes, Phys. Chem. Chem. Phys., 16, 7555 (2014).
11. A. Pimachev and Yu.
Dahnovsky, Electronic structure calculations of PbS
quantum rods and tubes, J. Appl. Phys. 115,
043705 (2014).
12. A. Pimachev, G. Kolesov, J. Chen, W.
Wang, and Yu. Dahnovsky, Internal
relaxation in dye sensitized solar cells based on Zn2SnO4 nanostructures,
J. Chem. Phys. 137, 244704- (2012).
13. G. Kolesov
and Yu. Dahnovsky, Correlated electron dynamics in quantum-dot
sensitized solar cell: Kadanoff-Baym versus Markovian approach, Phys. Rev. B 85,
241309(R) (2012).
14. Yu. Dahnovsky, Quantum correlated electron dynamics in a
quantum-dot-semiconductor solar cell: Keldysh
function approach, Phys. Rev. B 83, 165306 (2011).
15. G. Kolesov
and Yu. Dahnovsky, Quantum correlation effects in electron dynamics in
molecular wires and solar cells: The nonequilibrium Green's function approach,
Adv. Quant. Chem. 61, 261
(2011).
16. A. Pimachev, G.
Kolesov, J. Chen, W. Wang, and Yu. Dahnovsky,
Internal relaxation in dye sensitized solar cells based on Zn2SnO4
nanostructures, J. Chem. Phys. 137, 244704- (2012).
17. W. D. Wheeler and Yu.
Dahnovsky, Molecular transistors with perpendicular gate field
architecture: A strong gate field effect, J. Phys. Chem. C 113,
1088-1092 (2009). http://pubs.acs.org/doi/pdfplus/10.1021/jp808631z
18. Yu. Dahnovsky,
Electron-electron correlations in molecular tunnel junctions: A diagrammatic
approach, Phys. Rev. B 80, No. 16, 165305 (2009).
19. V.
Ch. Zhukovsky, Yu. I Dahnovsky, O. N. Gorshkov, V. D. Krevchik, M. B.
Semenov, Yu. G. Smirnov, E. V. Chuprunov, V. A. Rudin, N. Yu. Skiittskaya, P. V. Krevchik, D. O. Filatov, D. A. Antonov, M. A. Lapshina, and K Yamamoto, Observed two-dimensional
tunneling bifurcations in external electric field, Vestik
Moscow State University, No. 5, 3-8, (2009).
20. W.
D. Wheeler and Yu. Dahnovsky, Molecular transistors with perpendicular
gate field architecture: A strong gate field effect, J. Phys. Chem. C 113,
13769-13774 (2009).
21. W.
D. Wheeler and Yu. Dahnovsky, Molecular transistors based on BDT-type
molecular bridges, J. Chem. Phys. 2008, 129, 164112 (2008).
22. W.
Wheeler and Yu. Dahnovsky, Quantum Interference in Molecular Wire:
Electron Propagator calculations, J. Phys. Chem. C 112, 13769-74 (2008).
23. A.
Kletsov and Yu. Dahnovsky, Ab
initio electron propagator calculations in molecular transport junctions:
Predictions of negative differential resistance, Journ.
Chem. Phys. 127,
144716 (2007).
24. Yu. Dahnovsky,
A. Kletsov, and J. V. Ortiz, Ab
initio electron propagator theory in molecular wires: Analytic properties of
the transmission function, J. Chem Phys. (submitted)
(2008).
25. M.
R. Sterling, O. Dolgunitcheva, V. G. Zakrzewski, Yu. Dahnovsky, and J. V. Ortiz,
Correlated, Ab Initio electron propagators in the
study of molecular wires: Application to a single molecular bridge placed
between two model leads, Intern. Journ. Quant. Chem. 107,
329 ( 2007).
26. A.
Kletsov and Yu. Dahnovsky, Surface Green
functions in molecular transport junctions: Generalization to interacting
electrons in the leads, Phys. Rev. B 76, 035304 (2007).
27. Yu. Dahnovsky, Ab initio electron propagators in molecules with strong
electron-electron interaction. II. Electron GreenÕs function, Journ. Chem. Phys. 127, 014104 (2007).
28. Yu. Dahnovsky, Ab initio electron propagators in molecules with strong
electron-electron interaction. I. Phonon averages, Journ.
Chem. Phys. 126, 234111 (2007).
29. A.
Kletsov, Yu. Dahnovsky, and J. V. Ortiz,
Surface Green function calculations in the infinite number of principal layer
approach: A non-recursive scheme, J. Chem. Phys. 126, 134105 (2007).
30. O.
Dolgounitcheva, V. G. Zakrzewski,
A. Kletsov, M. R. Sterling ,
Yu. Dahnovsky and J. V. Ortiz, Correlated, Ab Initio Calculations in the Study of Molecular Wires, Int. Journ. Quant. Chem.
106, 3387 – 3392
(2006).
31. Yu. Dahnovsky,
Modulating electron transfer: Modified spin-boson approach, Phys. Rev. B 73,
144303 (2006).
32. Yu. Dahnovsky
and J. V. Ortiz, Ab Initio electron propagator theory of
molecular wires: II. Multiorbital terminal
description, Journ. Chem. Phys. 124, 144114 (2006).
33. Yu. Dahnovsky, V.
G. Zakrzewski, A. Kletsov,
and J. V. Ortiz, Ab Initio electron propagator theory of
molecular wires: I. Formalism, Journ. Chem. Phys. 123,
184711 (2005).
34. J.T. York, R.D. Coalson, and Yu.I. Dahnovsky, Control of electron current
by double-driven structures using pulsed laser fields, in Transfer Processes in
Low-Dimensional Systems, Ed. Yu.I. Dahnovsky,
V.D. Krevchik, V.Ya. Krivnov, M.B. Semenov, and K. Yamamoto (UT Research
Institute Press, Tokyo, 2005) p. I-272.
35. J.T. York, R.D. Coalson, and Yu.I. Dahnovsky, Control of electron current
by double-driven structures using pulsed laser fields, in Transfer Processes in
Low-Dimensional Systems, Ed. Yu.I. Dahnovsky,
V.D. Krevchik, V.Ya. Krivnov, M.B. Semenov, and K. Yamamoto (UT Research Institute
Press, Tokyo, 2005) p. I-272.
36. Yuri Dahnovsky, Electron tunneling dynamics in anharmonic
bath, in Transfer Processes in Low-Dimensional Systems, Ed. Yu.I. Dahnovsky, V.D. Krevchik, V.Ya. Krivnov, M.B. Semenov, and
K. Yamamoto (UT Research Institute Press, Tokyo, 2005) p. I-337.
37. Yu.I. Dahnovsky, V.D. Krevchik, E.I. Kudryashov, V.G. Mayorov, M.B.
Semenov, V.Ch. Zhukovsky, and K. Yamamoto, One -
dimensional quantum dissipative tunneling in structures with quantum dots, in Transfer Processes in
Low-Dimensional Systems, Ed. Yu.I. Dahnovsky, V.D. Krevchik, V.Ya.
Krivnov, M.B. Semenov, and K. Yamamoto (UT Research
Institute Press, Tokyo, 2005) 2005, p. I-346.
38. Yu.I. Dahnovsky and M.B. Semenov, Tunneling
of two interacting particles : transition between
separate and cooperative tunneling, in Transfer Processes in Low-Dimensional
Systems, Ed. Yu.I. Dahnovsky, V.D. Krevchik,
V.Ya. Krivnov, M.B.
Semenov, and K. Yamamoto (UT Research Institute Press, Tokyo, 2005) p. II-374.
39. A.K. Aringazin,
Yu.I. Dahnovsky,
V.D. Krevchik, M.B. Semenov, A.A. Ovchinnikov,
V.A. Veremyev, and K. Yamamoto, Two-dimensional tunnel correlations with dissipation, in Transfer
Processes in Low-Dimensional Systems, Ed. Yu.I. Dahnovsky, V.D. Krevchik, V.Ya. Krivnov, M.B. Semenov, and
K. Yamamoto (UT Research Institute Press, Tokyo, 2005) p. II-406.
40. A.K. Aringazin,
Yu.I. Dahnovsky,
V.D. Krevchik, M.B. Semenov ,
A.A. Ovchinnikov, V.A. Veremyev,
and K. Yamamoto, Two –
dimensional tunnel bifurcations with dissipation, in Transfer Processes in
Low-Dimensional Systems, Ed. Yu.I. Dahnovsky,
V.D. Krevchik, V.Ya. Krivnov, M.B. Semenov, and K. Yamamoto (UT Research
Institute Press, Tokyo, 2005) p. II-410.
41. Yuri Dahnovsky, , V. G Zakrzewski,
A. Kletsov and V. J. Ortiz, Ab
initio electron propagator theory of molecular wires I. Formalism, Journal of
Chemical Physics, 123, p. 184711
(2005)
42. Yuri Dahnovsky, Electron tunneling
dynamics in anharmonic bath, J. Chem. Phys. 122, 044501 (2005).
43.
Dahnovsky Yuri, Krevchik
V.D., Semenov M.B., Mayorov V.G., Kudryashov
E.I., Yamamoto K. One-dimensional
dissipative tunneling in structures with quantum dots (in Russian)//
Transactions of the Volga River Region Universities (Natural Sciences). 2004. N
5(14). p. 202 – 212.
44.
Dahnovsky Yu.I., Krevchik V.D., Semenov
M.B., V.Ch. Zhukovsky, Yamamoto K., Kudryashov E.I., Mayorov
V.G. 1D dissipative tunneling in
structures with quantum dots, role of angarmonicity
// Transactions of the Volga River Region Universities (Natural Sciences).
2004. N 6(15). p. 195-211.
45. Aringazin A.K., Dahnovsky Yu.I, Krevchik
V.D., Ovchinnikov A.A., Semenov M.B., V.A. Veremyev, Yamamoto K., Kudryashov
E.I., Mayorov V.G. The features of two-dimensional tunnel
bifurcations with dissipation // Transactions of the Volga River Region
Universities (Natural Sciences). 2004. N 6(15). C. 170-194.
46. Jaremy Creechley and Yuri
Dahnovsky, 2004, Vibrational
coherence in electron transfer: An exactly solvable
model, Chem. Phys. 296, 171 (2004).
47.
A.K. Aringazin, Yu. Dahnovsky, V.D. Krevchik, M.B.
Semenov, V.A. Veremyev, A.A. Ovchinnikov,
K. Yamamoto, 2004, Two-dimensional
tunnel bifurcations with dissipation, Hadronic
Journal, 27, No 2, p. 115-150,
(2004).
48. A. K. Argingazin, Yu.
Dahnovsky, A. A. Ovchinnikov, V. D. Krevchik, M. B. Semenov, and K. Yamamoto, 2003,
Two-dimensional tunnel correlations with dissipation, Phys. Rev. B 68,
155426.
49. Yu. Dahnovsky, 2003, Study of electron transport
in the model of a strong coupling for molecular wires in an external field: A Floquet approach, Izvestia Vuzov (in Russian), 2,
No 5, pp. 171-198.
50. Yu. Dahnovsky, Radiation of electron transport in a molecular wire
in a strong electric field in the tight binding approximation: Application to xylyl-dithiol, Izvestia Vuzov Volga
Region (in Russian), 1, No 6, pp.
150-174 (2003).
51. J. T. York, R. D. Coalson,
and Yu. Dahnovsky, 2002, Control of Electron Current by
Double Barrier Structures in Electronic Molecular Devices. Phys. Rev. B. 65, 23521.
52. Yu. Dahnovsky, A. A. Ovchinnikov,
and M. B. Semenov, 2002, Quantum Tunneling with Dissipation, Hadronic
Physics, 25, 1.
53. J. L. Cash
and Yuri Dahnovsky, 2001, Driven
Electron Transfer in an Environment with Slow and Fast Degrees of Freedom,
Phys. Rev. E, 63, 16014.
54. J. T. York and Yu. Dahnovsky, 2001, The transfer of an electron driven by laser in
electronic molecular devices, J. Phys. Chem. B, 105, 8278.
55. J. D. Bodyfelt and Yuri
Dahnovsky, 2002, Coherent and Incoherent Photo-Assisted Electron Tunneling in
Optoelectronic Molecular Devices in Soft Solids, Phys. Rev. B, 65,
45301.
56. A. Tikhonov, R. D. Coalson, and Yu. Dahnovsky, 2002,
Calculating Electron transport in tight-binding model of a field-driven
molecular wire: Floquet theory approach, J. Chem.
Phys. 116, 10909.
57. A. Tikhonov, R. D. Coalson, and Yu. Dahnovsky, 2002,
Calculating Electron transport in tight-binding model of a field-driven
molecular wire: Application to Xylyl-Dithiol, J.
Chem. Phys. 117, 567.
58. D. A. Tibbets and Yu. Dakhnovskii, 2000,
Electron transfer via a polar medium: Modulation and
solvation. Journ. Chem. Phys. 112, 5893.
59. Yu. I. Dakhnovskii, 1999, Electron transfer in a slow
relaxation bath: Fast and slow degrees of freedom: Application to primary
electron transfer in photosynthetic bacteria. Journal of Chem. Phys. 111, 5418.
60. M. J. Hornbach and Yu. I. Dakhnovskii, 1999,
Electron transfer in a slow bath: Coherence and non-exponential kinetics,
Journal of Chem. Phys. 111, 5073.
61. Yu. I. Dakhnovskii, V. Lubchenko, and R.
D. Coalson,
1998, Induced Irradiance in Laser
Control Chemical Reaction: Long Range Electron Transfer Driven by Two Lasers. Journ. Chem. Phys. 108,
691.
62. Yu. I. Dakhnovskii, V. Lubchenko, and R.
D. Coalson,
1996, Multi-Photon Absorption by
Metal-Metal Long Distance Charge Transfer Complexes in Polar Solvents. Journ. Chem. Phys. 105,
9441.
63. Yu.I.Dakhnovskii and V.Lubchenko, 1996,
Response to Comment on the Effect of Charged Impurities on a Glass Transition
in a Polar Medium. Journ. Chem. Phys. 105, 8959.
64. Yu. I. Dakhnovskii, V. Lubchenko, and R.
D. Coalson,
1996, Light Absorption in Strongly
Irradiated Long Range Polar Electron Transfer. Phys.Rev.Lett.
77, 2917.
65. R. D. Coalson, D. G. Evans, and Yu. I. Dakhnovskii, 1996,
Laser Control of Polar Electron Transfer. in Femptochemistry
ed. M. Chergui (World Scientific, Singapore, p.338.
66. Yu. I. Dakhnovskii, R. Bavli, and H. Metiu, 1996, Localization and Delocalization
in Biased and Unbiased Quantum Wells Driven by Mono- and Bichromatic
Laser Field. Phys. Rev. B 53, 4657.
67. Yu. I. Dakhnovskii, V. Lubchenko, and P.
Wolynes, 1996,
ÒFalse-TunnelingÕÕ and Multi-Relaxation Time Non-Exponential Kinetics of
Electron Transfer in Polar Glasses. Journ. Chem.
Phys. 104, 1875.
68. Yu. I. Dakhnovskii and V. Lubchenko, 1996, The
Effect of Charged Impurities on a Glass Transition in a Polar Medium. Journ. Chem. Phys. 104,
664.
69. D. Evans, R.
D. Coalson, and Yu. I. Dakhnovskii, 1996,
Induced Oscillations in an Electron Transfer Reaction in the Presence of a Bichromatic Field. Journ. Chem.
Phys. 104, 2287.
70. D. Evans, R.
D. Coalson, H. Kim, and Yu. I. Dakhnovskii, 1995, Inducing Coherent Oscillations in the Electron Transfer
Dynamics of a Strongly Dissipative System with Pulsed Monochromatic Light. Phys.Rev.Lett. 75,
3649.
71. Yu. I. Dakhnovskii, H. Kim, D. Evans, and R. D. Coalson, 1995, Effect of Laser Field on
Electron Transfer in Metal Complexes: Quantum Degrees of Freedom. Journ. Chem. Phys. 103,
5461.
72. Yu. I. Dakhnovskii and H. Metiu, 1995, An
Absolute Negative Resistance in Double-Barrier Heterostructures
in a Strong Laser Field. Phys. Rev. B 51,
4193.
73. Yu.I.Dakhnovskii and R. D. Coalson, 1995,
Manipulating of Reactant-Product Distributions of Electron Transfer Reactions
in a Laser Field. Journ. Chem. Phys. 103, 2908.
74. Yu. I. Dakhnovskii, B. Barsulaya, and H.
Kim, 1995, Quantum Tunneling in Anharmonic
Classical Bath: Enhanced Kinetic Isotope Effect in an Arrhenius Region. Journ. Chem. Phys. 102,
738.
75. Yu. I. Dakhnovskii and R. Bavli, 1994,
Stable and Unstable Localization in Two-Level Systems Driven by Two
Time-Dependent Fields. Journ. Phys. Chem. 98, 9777.
76. Yu. I. Dakhnovskii, R. Doolen, and J.
Simon, 1994, Electron Transfer in the Marcus Inverted region: Experiment
and Adiabatic Tunneling Mechanism. Journ. Chem. Phys.
101, 6640.
77. Yu.I.Dakhnovskii, 1994, Dynamics of Inner- and Outer
Sphere Electron transfer in a Polar Solvent, Journal of Molecular Liquids 60, 73.
78. Yu. I. Dakhnovskii and M. B. Semenov, 1994, Tunneling of Two Interacting Particles Moving
Parallel and Antparallel: a Comparative Analysis.
Chemical Physics 183, 1.
79. Yu. I. Dakhnovskii, 1994, Non-Adiabatic Chemical Reactions
in a Strong Time-Dependent Electric Field: An Electron Transfer Reaction in a
Polar Solvent. Journ. Chem. Phys. 100, 6492.
80. Yu. I. Dakhnovskii, 1994, Dynamics of a Two-Level System
with Ohmic Dissipation in a Time-Dependent
Field. Phys. Rev. B 49, 4649.
81. Yu.I.Dakhnovskii, 1994, Quantum Coherence of a Two Level
System Interacting with a Strong Time-Dependent Electric Field. Annals of
Physics 229, 145.
82. Yu. I. Dakhnovskii, R. Bavli, and H. Metiu, 1993, Optical Response of a Double
Quantum Well Driven by Two Lasers: Localization and Low Frequency Generation.
Report No-AD-A265118. Avail. NTIS,
From Govern. Report Announce. Index (US)
93(18) (1993), Abstr. No 355, 714.
83. Yu. I .Dakhnovskii and R. Bavli, 1993, Emission Spectrum and
Localization of Electrons in Quantum Well Systems Induced by a Strong Laser
Field. Phys. Rev. B 48, 11020.
84. Yu. I. Dakhnovskii and R. Bavli, 1993,
Selective Manipulation of Emission Spectrum of an Electron in a Biased Double
Well Heterostructures Driven by a Free Electron
Laser. Phys. Rev. B 48, 11010.
85. Yu. I. Dakhnovskii, 1993, Adiabatic Electron Transfer in
Polar Solvents. Crossover from Activation Transfer to Tunneling. Journ. Chem. Phys.
99, 7718.
86. Yu. I. Dakhnovskii and R. Bavli, 1993, A
Two-Level System in a Strong Laser Field: Comparative Analysis Between the Landau-Lifshitz Solution, and an Exact Numerical One. Phys. Rev. A
48, R886.
87. K. A. Pronin, Yu. I. Dakhnovskii and A.
Bandrauk, 1993, Nonlinear Optical Properties of
Conjugated Polymers in SSH Model: 4 Wave Mixing. Synthetic Metals 57, 3907.
88. Yu. I. Dakhnovskii and K. A. Pronin, 1993,
Nonlinear Optical Properties of Conjugated Polymers in SSH Model: Third
Harmonic Generation. Synthetic Metals 54,
295.
89. Yu. I. Dakhnovskii and H. Metiu, 1993,
Conditions leading to intense low-frequency generation and strong localization
in two -level systems. Phys. Rev. A 48,
2342.
90. Yu. I. Dakhnovskii,
A. A. Ovchinnikov, and Z. K. Smedarchina, Charge Tunneling in a Classical Medium. Khimicheskaya Fizika 10, 930 (1991) (Sov. Chem. Phys 10, 1438 (1993)).
91. Yu. I. Dakhnovskii and E. N. Dolgov, 1992,
Remarks on Some Problems in 1D-Physics: Nonlinear Optics of (A-B)-Polymers and
the Role of Electron-Electron Scattering in Conducting Q1D Materials with a
Soft Phonon Mode. Sensors and Actuators 33,
123.
92. Yu. I. Dakhnovskii and M. B.S Semenov, Tunneling of Two Interacting Particles moving
parallel and Anti-Parallel. Khimicheskaya Fizika 11, 738 (1992) (Sov.
Chem. Phys 11, 1080 (1993)).
93. Yu. I. Dakhnovskii, Proton
Transfer in a Polar Solvent, 1992,
(T. Bountis, ed.) NATO ASI Series B291, 313.
94. Yu. I. Dakhnovskii and A. Bandrauk, 1991,
Nonlinear Optical Properties of (A-B)-Polymers. Lecture and Notes in Physics Correlated Effects in Low Dimensional
Systems (Springer, Berlin).
95. Yu. I. Dakhnovskii and K. A. Pronin, 1991,
Nonlinear Optical Properties of ``CombinedÕÕ Polymer Dielectric. Lecture and
Notes in Physics Correlated Effects in
Low Dimensional Systems (Springer, Berlin).
96. Yu. I. Dakhnovskii and V. V. Nefedova, 1991,
Tunneling in an Anharmonic Liquid. Zh. Eksp. Teor.
Fiz. Soviet Phys. JETP 100, 892 (Soviet Phys. JETP 73,
492 ).
97. Yu. I. Dakhnovskii and V. V. Nefedova, 1991,
Particle Tunneling in a Classical Anharmonic Bath.
Physics Lett. 157
A, 301.
98. Yu. I. Dakhnovskii and A. Bandrauk, 1991,
Nonlinear Optical Properties of (A-B)-Polymers. Synthetic Metals 41-43, 3747.
99. K. A. Pronin and Yu. I. Dakhnovskii, 1991,
Nonlinear Optical Properties of Conjugated Polymers. Synthetic Metals 41-43, 3758.
100.
Yu. I. Dakhnovskii, A. A. Ovchinnikov, and Z. K. Smedarchina, 1990,
Charged Particle Transfer in a Polar Liquid. Physics Lett.
149 A, 43.
101.
Yu. I. Dakhnovskii and A. A.
Ovchinnikov,
1990, Quantum Tunneling in a High
Temperature Boson Bath. Physics Lett. 149 A, 39.
102.
Yu. I. Dakhnovskii, Non-Condon Effects in Transfer a Particle in a
Condensed Phase. Khimicheskaya Fizika 9, 536 (1990) (Sov. Chem. Phys. 8, 890 (1991)).
103.
Yu. I. Dakhnovskii and M. B.
Semenov, 1989, Tunneling of Two Interacting Particles. Journ.
Chem. Phys. 91, 7606.
104.
Yu.I.Dakhnovskii, A. A. Ovchinnikov, and M. B. Semenov, 1988, A
Low Temperature Chemical Reaction in a Condensed Phase. Molecular Physics 63, 497.
105.
Yu.I.Dakhnovskii, A.A.Ovchinnikov, and M.B.Semenov, Low Temperature Chemical Reactions Considered as
Dissipative Tunnel Systems, Zh.Eksp.Teor.Fiz. 92, 995 (1987) (Soviet Phys. JETP 65,
541 (1987)).
106.
Yu. I. Dakhnovskii and A. A.
Ovchinnikov,
1987, Quantum Theory of the
Transition State, Zhurnal Fizicheskoi
Khimii 61,
766, (Russian Journal of Physical Chemistry 61, 396).
107.
Yu. I. Dakhnovskii and A. A.
Ovchinnikov,
1986, Adiabatic Electron Transfer in
Polar Media: Quantum Transition State Theory. Molecular Physics 58, 237.
108.
Yu. I. Dakhnovskii and A. A.
Ovchinnikov,
1986, Quantum Transition State
Theory: Transport of a Heavy Particle. Journal of Electroanal.
Chemistry 204, 85.
109.
Yu. I. Dakhnovskii and A. A.
Ovchinnikov,
Adiabatic Electron Transfer in a Polar Solvent. Inclusion of Quantum Degrees of
Freedom. Khimicheskaya Fizika
5, 649 (1986) (Sov. Chem. Phys 5, 1019 (1990)).
110.
Yu. I. Dakhnovskii and A. A.
Ovchinnikov,
Transition State Theory and the Generalized Kramers Model.
Khimicheskaya Fizika 5, 36 (1986) (Sov. Chem. Phys. 5, 59 (1989)).
111.
Yu. I. Dakhnovskii and A. A.
Ovchinnikov,
1985, Decay of a Metastable State:
Comparison between the Transition State Theory and Generalized Kramers Model. Physics Lett. 113 A, 147.
112.
Yu. I. Dakhnovskii and A. A.
Ovchinnikov,
1983, Charge Transfer in Polar
Media. Transition State Entropy. Chem. Physics 80, 17.
113.
Yu. I. Dakhnovskii, V. A. Benderskii, and A. A. Ovchinnikov, 1983,
Theory of Electrochemical Hydrogen Evolution Reactions. Part 2. Model of
Harmonic Proton Terms of Different Frequencies. Journal of Electroanalytical
and Interface Chemistry 148, 161.
114.
Yu. I. Dakhnovskii and A. A.
Ovchinnikov,
1983, Adiabatic Theory of Charge
Transfer in a Polar Medium. Dokl. Akad.
Nauk USSR, Ser. Phys. Chem. 270, 119, (Dokl. Phys. Chemistry 270, 298).
115.
V. A. Benderskii, Yu. I. Dakhnovskii, and A. A. Ovchinnikov, 1983,
Theory of Electron-Proton Transfer Reactions in a Polar Medium. Dokl. Akad. Nauk
USSR, Ser. Phys. Chem. 269, 1112, (Dokl. Phys. Chemistry 269,
243).
116.
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