Nanoscience, Nanooptics and Nanotechnology



Atom nanooptics

 

522.          The Possibility of deep laser focusing of an atomic beam into the Å-region.

V.I. Balykin, and V.S. Letokhov.

            Optics Comm. 64, ¹2, 151-156 (1987).

 

529.     Deep focusing of an atomic beam into an A-size region by means of laser

            radiation.

            V.I. Balykin, and V.S. Letokhov.

Zh. Eksp. Teor. Fiz. 94, ¹1, 140-150 (1988) (in Russian); [Sov. Phys.-JETP 67(1),
78-83 (1988)].

 

555a.   Laser optics of neutral atomic beams.

V.I. Balykin, V.S. Letokhov.

Physics Today, April 1989, pp. 23-28.

 

555b.   Laser optics of neutral atomic beams.

V.I. Balykin, V.S. Letokhov.

Uspekhi Fiz. Nauk 160, ¹1, 141-154 (1990) (in Russian).

           

607.     Atomic optics with tunable Dye lasers.

            V.S. Letokhov.

            In: Dye Lasers: 25 Fears, ed. by M.Stuke (Springer-Verlag, Berlin, 1992),

153-168.

 

641.     Tight Focusing of an Atomic Beam by the Near Field of Diffracted Laser Light.

            V.I. Balykin, V.S. Letokhov, V.V. Klimov.

            Pis’ma ZhETF 59, ¹4, 219-222 (1994); [JETP Lett. 59, 235-238 (1994)].

 

653.     Laser Near Field Lens for Atoms.

           V.I. Balykin, V.V. Klimov, V.S. Letokhov.

            J. Phys. II. France 4, 1981-1997 (1994).

 

669.          Laser-near-field-based atomic lens: quantum wave optics consideration.

            V.V. Klimov, V.S. Letokhov.

            J. Modern Optics 42, ¹7, 1485-1503 (1995).

           

687.     Atom Optics in Laser Near Field.

            V.V. Klimov and V.S. Letokhov.

            Laser Physics 6, 475-500 (1996).

 

732.     Near Field Diffraction Grating for Atoms.

V.I. Balykin, D.A. Lapshin, M.V. Subbotin, V.S. Letokhov.

Optics Comm. 145, 322-328 (1998).

 

755.     Exact Solution of Problem on Laser Focusing of an Atomic Beam.

            V.V. Klimov, V.S. Letokhov.

Pis’ma ZhETF 70, 654-659 (1999); [JETP Lett. 70, 666-672 (1999)].

 

803.     Laser Focusing of Cold Atoms: Analytical Solution of the Problem.

V.V. Klimov and V.S. Letokhov.

Laser Physics 13(3), 339-349 (2003).

 

811.     Atom Nanooptics Based on “Photon Dots” and “Photon Holes”.

V.I. Balykin, V.V. Klimov, V.S. Letokhov.

Pis’ma Zh. Eksp. Teor. Fiz. (Russian) 78, ¹1, 11-15 (2003); [JETP Lett. 78(1), 8-12 (2003)].

 

837.     Atom Nanooptics.

V.I. Balykin, V.V. Klimov, V.S. Letokhov.

In “Handbook of Theoretical and Computational Nanotechnology”, ed. by M. Reith
and W. Schommers (Amer. Sci. Publ.), vol. 7, 1-78 (2006).

 

 

Photoelectron/photoion microscopy with nanoresolution

 

166.     The use of laser radiation in autoelectron and autoion microscopy for the
o
bservation of biomolecules.

            V.S. Letokhov.

Kvantovaya Elektronika 2, ¹5, 930-937 (1975) (in Russian); [Sov. J. Quant. Electr. 5, 506 (1975)].

 

168.     Possible laser modification of field ion microscopy.
            V.S. Letokhov.

            Phys. Lett. 51A, ¹4, 231-232 (1975).

 

361a.   Laser visualization of molecules and spatial localization of molecular bonds.

V.S. Letokhov.

Comm. Atom. and Molec. Phys. 11, ¹1, 1-12 (1981).

 

389.     Observation of a Photoion Image in a laser desorption microscope.

            V.S. Letokhov, V.S. Likhachev, V.G. Movshev, and S.V. Chekalin.

            Kvantovaya Elektronika 9, ¹9, 2117-2118 (1982) (in Russian);
            [Sov. J. Qauntum Electron. 12, 1377-1378 (1982)].

 

428.     Laser Photoion Projector.

            S.V. Chekalin, V.S. Letokhov, V.S. Likhachev, and V.G. Movshev.

            Appl. Phys. B33, 57-61 (1984).

 

655.     Study of Surface of LiF:F Crystal with Subwavelength Spatial Resolution.

           V.N. Konopsky, S.K. Sekatskii, V.S. Letokhov.

            Pis'ma Zh. Eksp. Teor. Fiz. 60, 691-693 (1994) (in Russian); [JETP Lett. 60, 709-712
            (1994)].

 

678a.   First Realization of Laser Selective Projective Photoelectron Microscopy: Study of

            Surface of LiF:F2 Crystal with Subwavelength Spatial Resolution.

            V.N. Konopsky, S.K. Sekatskii, V.S. Letokhov.

            Izv. RAN, Fiz. seria (Proceed. of Russ. Acad. Sci., Phys. Seria) 59, B12, 13-18,

            (1995) (in Russian).

 

678b.   First Realization of Laser Selective Projection Photoelectron Microscopy: Studying
of LiF:F2 Crystal Surface with the Subwavelength Spatial Resolution.

            V.N. Konopsky, S.K. Sekatskii, V.S. Letokhov.

            Procced. of SPIE, “Atomic and Quantum Optics: High-Precision Measurements”,
            vol. 2799, 344-350 (1996).

 

682.     Laser Resonance Photoelectron Spectromicroscopy with a Subwavelength Spatial

Resolution.

V.S. Letokhov.

In: Quantum Optics of Confined Systems, ed. by M.Ducloy and D.Bloch (Kluwer

Academic Publ., Dordrecht, 1996), pp. 327-340.

 

685a.   Laser Photoionization Spectroscopy with Subwavelength Spatial Resolution:

            First Observation of Single Color Centers on the Surface.

            V.N. Konopsky, S.K. Sekatskii, V.S. Letokhov.

            In: Laser Spectroscopy XII Intern. Conf. (June 11-16, 1995, Capri, Italy) ed. by
            M. Inguscio, M. Allegrini, A. Sasso (World Scientific, Singapore, 1996), pp. 433-439.

 

689.     Laser Photoelectron Projection Microscopy with Subwavelength Spatial Resolution.

            V.N. Konopsky, S.K. Sekatskii, V.S. Letokhov.

            Applied Surface Science 94/95, 148-155 (1996).

 

694a.   Laser Resonance Photoelectron Microscopy with a Subwavelength-High Spatial
Resolution: the First Observation of Single Color-Centers on Surface.

            V.N. Konopsky, S.K. Sekatskii, V.S. Letokhov.

            Optics Comm. 132, 251-256 (1996).

 

694b.   Resonance Ionization Spectromicroscopy (RISM) with Subwavelength Spatial Resolution:
the First Observation of Single Color Centers.

            V.N. Konopsky, S.K. Sekatskii, V.S. Letokhov.

            In: “Resonance Ionization Spectroscopy 1996”, eds. N.Winograd, J. Parks, ATP
            Conference Proceeding, 388, Am. Ins. Ph., Woodbury, N.Y. (1997).

 

702.     Field- and Photoassisted Field Emission Studies of Calcium Fluoride Coated Silicon Tips.

            V.N. Konopsky, V.S. Letokhov, S.K. Sekatskii.

Journ. de Physique IV 6, c5-129-c5-134 (1996).

 

705.     Toward Direct Observation of the Atomic Structure of Biomolecules with Nanometer
Spatial Resolution by Visible Light.

            V.N. Konopsky, V.S. Letokhov.

            Laser Physics 7, 173-178 (1997).

 

711.     Observation of a Single Laser-Excited Center at the Point of a Crystaline Needle.

            S.K. Sekatskii, V.S. Letokhov.

Pis’ma Zh. Eksp. Teor. Fiz. 65, ¹6, 441-444 (1997); [JETP Lett. 65, 465-469 (1997)].

 

 728.     Laser-Excited One-Atom Source of Electrons.

            V.S. Letokhov, S.K. Sekatskii.

            Journ. of Nonlinear Optical Physics and Materials, 6, ¹4, 411-420 (1997).

 

741.     Photoselective Laser Photoion Microscopy with 5 nm Resolution.

            S.K. Sekatskii, D.V. Serebryakov, V.S. Letokhov.

            Pis’ma Zh. Eksp. Teor. Fiz. 67, ¹7, 450-454 (1998); [JETP Lett. 67,

            ¹7, 470-475 (1998)].

 

742.     Femtosecond Two-Photon Laser Photoelectron Microscopy.

S.K. Sekatskii, S.V. Chekalin, A.L. Ivanov, Yu.A. Matveets, A.G. Stepanov,

V.S. Letokhov.

Journ. Phys. Chem. A102, 4148-4153 (1998).

 

746.     Direct Observation of Light-Absorbing Nanocrystals in Glass Matrices by the Projection
Laser Photoion Microscopy Technique.

S.K. Sekatskii, D.V. Serebryakov, V.S. Letokhov.

Rev. Sci. Instr. 69, ¹11, 3885-3888 (1998).

 

748.     Field Desorption Imaging of Insulator Surfaces: High-Resolution Images of Calcium
Fluoride Epitaxial Layers
.

S.K. Sekatskii, D.V. Serebryakov, V.S. Letokhov, V.V. Zhirnov,

A.L.  Meshceryakova, J.C. Alvarez, N.S. Sokolov.

            Appl. Surface Science 140, 46-51 (1999).

 

756.     Projection Photoelectron Microscopy with Subwavelength Spatial

Resolution with Femtosecond Lasers.

S.K. Sekatskii, S.V. Chekalin, A.L. Ivanov, V.O. Kompanetz, Yu.A. Matveetz, A.G. Stepanov,
V.S.
Letokhov.

Zh. Eksp. Teor. Fiz. 115, 1680-1688 (1999); [JETP, ...]

 

760.     Laser Resonance Photoelectron/Photoion Microscopy with Subwavelength
Spatial Resolution.

            V.S. Letokhov, S.K. Sekatskii.

            In: “Advances in Laser Physics”, vol. 21, ed. by V. Letokhov, P. Meystre, “Laser Science
and Technology”, (Harwood Academic Publ.), p. 85-115 (2000).

 

761.     Quantitative Measurements of the Local Coefficient of Two-Photon Photoelectric

Effect by the Femtosecond Laser Photoelectron Microscopy.

S.K. Sekatskii, S.V. Chekalin, A.L. Ivanov, V.O. Kompanetz, Yu.A. Matveets, A.G. Stepanov,
and V.S.
Letokhov.

J. Nonlinear Optics 23, 157-170 (2000).

 

773.     Field-emission Projection Microscopy of Dielectrics with Ultrahigh Spatial Resolution.

            B.N. Mironov, D.A. Lapshin, S.K. Sekatskii, V.S. Letokhov.

            Pis’ma ZhETF 74, 263-268, (2001); [JETP Lett. 74 (4) 240-243, (2001)].

 

774.     Analysis of Scanning Near-Field Optical Microscopy Fiber Probes by Field Emission
Microscopy.

            S.K. Sekatskii, B.N. Mironov, D.A. Lapshin, G. Dietler, V.S. Letokhov.

            Ultramicroscopy 89 (1-3), 83-87 (2001).

 

806.     Nonperturbating Observation of Optical Near Field by Means of Two-Photon
Ionization by Ultrashort Laser Pulses.

S.K. Sekatskii, B.N. Mironov, V.O. Kompanets, Yu.A. Matveets, S.V. Chekalin,

G. Dietler, V.S. Letokhov.

Appl. Phys. Lett. 83(24), 4900-4902 (2003).

 

821.     Recording of near field in laser photoelectron microscope by means of two-photon
ionization by femtosecond laser pulses.

S.V. Chekalin, V.O. Kompanets, V.S. Letokhov, Yu.A. Matveets, B.N. Mironov
and S.K. Sekatskii.

Proceedings of SPIE, vol. 5402, 17-24 (2004).

 

822.     Photoelectron Femtosecond Laser Projection Microscopy of Organic Nanocomplexes.

S.A. Aseyev, B.N. Mironov, S.V. Chekalin, V.S. Letokhov.

            Pis’ma v ZhETF 80, ¹8, 645-649 (2004); [JETP Letters, 80(8), 568-571 (2004)].

 

830.     Laser femtosecond photoelectron microscopy of capillar nanotips with ultrahigh
spatial resolution.

B.N. Mironov, S.A. Aseyev, S.V. Chekalin, V.S. Letokhov.

Journal of Experimental and Theoretical Physics 128(4), 732-739 (2005);
[JETP 101(4), 628-634 (2005)].

 

 

Scanning near-field microscopy (SNOM)

 

634.     A Simple Theory of the Near Field in Diffraction by a Round Aperture.

V.V. Klimov, and V.S. Letokhov.

Optics Comm. 106, 151-154 (1994).

 

677.     New Atom Trap Configurations in the Near Field of Laser Radiation.

            V.V. Klimov, V.S. Letokhov.

            Optics Comm. 121, 130-136 (1995).

 

681.     Scanning Optical Microscopy with Nanometer Spatial Resolution Based on

Resonance Excitation of Fluorescence from One-Atom Excited Center.

S.K. Sekatskii, V.S. Letokhov.

Pis’ma Zh. ETF 63, ¹5, 311-315 (1996); [JETP Lett. 63, 319-323 (1996)].

 

697.     Single Fluorescence Centers on the Tips of Crystal Needles: First Observation and
           Prospects for Application in Scanning One-atom Fluorescence Microscopy.

            S.K. Sekatskii, V.S. Letokhov.

            Appl. Phys. B63, 523-530 (1996).

 

734.     Contact Scanning Optical Near-Field Microscopy.

D.A. Lapshin, V.N. Reshetov, S.K. Sekatskii, V.S. Letokhov.

Pis’ma Zh. Eksp. Teor. Fiz. 67, ¹4, 245-250 (1998) (in Russian); [JETP Lett. 67,

263-268 (1998)].

 

737.     Imaging of the Near-Field over the Reflection Phase Grating by the Apertureless
Photon Scanning Tunneling Microscope.

D.A. Lapshin, V.I. Balykin, V.S. Letokhov.

Journ. of Modern Optics 45, 747-758 (1998).

 

750.     Contact Mode Near-Field Microscopy.

            D.A. Lapshin, V.N. Reshetov, S.K. Sekatskii, V.S. Letokhov.

            Ultramicroscopy 76, 13-20 (1999).

 

753.     Investigation of Nanolocal Fluorescence Resonance Energy Transfer for

Scanning Probe Microscopy.

G.I. Shubeita, S.K. Sekatskii, M. Chergui, G. Dietler and V.S. Letokhov.

Appl. Phys. Lett. 74, ¹23, 3453-3455 (1999).

 

762.     Shear Force Distance Control in Near-Field Optical Microscopy: Experimental

Evidence of the Frictional Probe-Sample Interaction.

            D.A. Lapshin, E.E. Kobylkin, and V.S. Letokhov.

            Ultramicroscopy 83, 17-23 (2000).

 

766.     Towards the Fluorescence Resonance Energy Transfer (FRET) Scanning Near-Field
Optical Microscopy: Investigation of Nanolocal FRET Processes and FRET
Probe Microscope.

            S.K. Sekatskii, G.T. Shubeita, M. Chergui, G. Dietler, B.N. Mironov, D.A. Lapshin,
V.S. Letokhov.

            Zh. Eksp. Teor. Fiz. 117, 885-894 (2000); [J. Exp. Teor. Phys. 90, 769-777 (2000)].

 

774.     Analysis of Scanning Near-Field Optical Microscopy Fiber Probes by Field Emission
Microscopy.

            S.K. Sekatskii, B.N. Mironov, D.A. Lapshin, G. Dietler, V.S. Letokhov.

            Ultramicroscopy 89 (1-3), 83-87 (2001).

 

788.     Tuning-Fork Based Fast Highly-Sensitive Surface-Contact Sensor for AFM/SNOM.

            D.V. Serebryakov, A.P. Cherkun, B.A. Loginov, V.S. Letokhov.

            Rev. Sci. Instr. 73, 1795-1802 (2002).

 

789.     Local Fluorescent Probes for the Fluorescence Resonance Energy Transfer Scanning
Near-Field Optical Microscopy.

G.T. Shubeita, S.K. Sekatskii, G. Dietler, V.S. Letokhov.

Appl. Phys. Lett. 80, 2625-2627 (2002).

 

791.     A Model of an Apertureless Near-Field Scanning Microscope with a Prolate
Nanospheroid as a Tip and Excited Molecule as an Object.

V.V. Klimov, M. Ducloy, V.S. Letokhov.

Chem. Phys. Lett. 358, 192-198 (2002).

 

806.     Nonperturbating Observation of Optical Near Field by Means of Two-Photon
Ionization by Ultrashort Laser Pulses.

S.K. Sekatskii, B.N. Mironov, V.O. Kompanets, Yu.A. Matveets, S.V. Chekalin,

G. Dietler, V.S. Letokhov.

Appl. Phys. Lett. 83(24), 4900-4902 (2003).

 

818.     Shear Force Distance Control in a Scanning Near-Field Optical Microscope:
in Resonance Excitation of the Fiber Probe versus out of Resonance Excitation.

D.A. Lapshin, V.S. Letokhov, G.T. Shubeita, S.K. Sekatskii and G. Dietler.

            Ultramicroscopy 99, Issue 4, 227-233 (2004).

 

823.     Nanooptics: Atoms in the Near Field.

V.S. Letokhov.

In “Tribute to Emil Wolf”, SPIE (Press, 2004), 477-490.

 

825.     Atom Nanooptics.

V.I. Balykin, V.V. Klimov, V.S. Letokhov.

Optics Photonics News 16, ¹3, 44-48 (2005).

 

836.     Double-Resonance Probe for Scanning Near-Field Optical Microscopy.

A.P. Cherkun, D.V. Serebryakov, S.K. Sekatskii, I.V. Morozov, and V.S. Letokhov.

            Rev. Sci. Instr. 77, 033703 (2006).

 

845.     Scanning near-field optical microscope based on a double resonant fiber probe
montage and equipment with time-gated photon detection.

D.V. Serebryakov, S.K. Sekatskii, A.P. Cherkun, K. Dukenbayev, I.V. Morozov, V.S. Letokhov,
G. Dietler.

Journ. of Microscopy (in press).

 

850.     Single molecule fluorescent resonance energy transfer scanning near-field optical microscopy.

S.K. Sekatskii, G. Dietler, V.S. Letokhov.

Chem. Phys. Lett. (in press).

 

 

Atom near nanobodies

 

680.     Increase of Spontaneous Quadrupole Transition Rate in the Vicinity of a Dielectric

Microsphere.

V.V. Klimov and V.S. Letokhov.

Optics Comm. 122, 155-162 (1996).

 

683.     Spontaneous Emission Rate and Level Shift of an Atom inside a Dielectric

Microsphere.

V.V. Klimov, M. Ducloy, V.S. Letokhov.

Journ. Modern Optics 43, ¹3, 549-563 (1996).

 

695.     Radiative Frequency Shift and Linewidth of an Atom Dipole in Vicinity of a
Dielectric Microsphere.

            V.V. Klimov, M. Ducloy, V.S. Letokhov.

            Journ. of Modern Optics 43, 2251-2267 (1996).

 

696.     Quadrupole Radiation of an Atom in the Vicinity of Dielectric Microsphere.

            V.V. Klimov, V.S. Letokhov.

            Phys. Rev. A 54, ¹3, 4408-4423 (1996).

 

708.     Vacuum Splitting of the Energy Levels of a System Consisting of an Atom and a
            Dielectric Microsphere.

            V.V. Klimov, V.S. Letokhov.

            Zh. Eksp. Teor. Fiz. 111, 44-51 (1997); [JETP 84(1), 24-28 (1997)].

 

712.     Vacuum Rabi Splitting of an Atom Dipole near a Dielectric Microsphere.

V.V. Klimov, M. Ducloy, V.S. Letokhov.

Journ. Modern Optics 44, ¹6, 1081-1092 (1997).

 

719.     Vacuum Rabi Splitting of Energy Levels in a Strongly Coupled System of Two-level
Atom and Dielectric Microsphere.

            V.V. Klimov, M. Ducloy, V.S. Letokhov.

            Phys. Rev. A56, ¹3, 2308-2315 (1997).

 

738.     Resonance Energy Exchange at Nanoscale Curved Interface.

V.V. Klimov, V.S. Letokhov.

Chem. Phys. Lett. 285, 313-320 (1998).

 

743.     Resonance Fluorescence of System “Atom + Dielectric Microsphere”, excited

by Single Photon.

V.V. Klimov, V.S. Letokhov.

Pis’ma ZhETF 68, 115-120 (1998); [JETP Lett. 68, 124-130 (1998)].

 

744.     Resonance Interaction between Two Atomic Dipoles Separated by the Surface
of a Dielectric Nanosphere.

V.V. Klimov, V.S. Letokhov

Phys. Rev. A58, 3235-3247 (1998).

 

749.     Enhancement and Inhibition of Spontaneous Emission Rates in Nanobubbles.

            V.V. Klimov and V.S. Letokhov.

            Chem.Phys. Lett. 301, 441-448 (1999).

 

751.     Strong Interaction between a Two-level Atom and the Whispering Gallery

Modes of a Dielectric Microsphere: Quantum-Mechanical Consideration.

            V.V. Klimov, M. Ducloy, V.S. Letokhov.

            Phys. Rev. A59, ¹4, 2996-3014 (1999).

 

754.     Two-photon Fluorescence Spectrum of “Atom + Dielectric Microsphere” System.

V.V. Klimov, V.S. Letokhov.

Pis’ma ZhETF 70, 192-197; [JETP Lett. 70, ¹3, 189-195 (1999)].

 

763.     Effect of the Curvature of Nanostructures on Radiative Multipole Transitions Rates.

V.V. Klimov, V.S. Letokhov.

            Comm. Modern Phys. 2(1), D15-27 (2000).

 

782.     Spontaneous Emission of Atoms in the Vicinity of Nanobodies.

            V. Klimov, M. Ducloy, V. Letokhov.

            Kvantovaya Elektronika 31, ¹7, 569-586 (2001); [Quantum Electronics 31(7),
            569-5
86 (2001)].

 

790.     Spontaneous Emission of an Atom Placed Near Prolate Nanospheroid.

V.V. Klimov, M. Ducloy, V.S. Letokhov.

European Journ. of Physics D20, 133-148 (2002).

 

827.     Electric and Magnetic dipole transitions of an atom in the presence of
Spherical Dielectric Interface.

V.V. Klimov and V.S. Letokhov.

Laser Physics, 15(1), ¹1, 61-73 (2005).

 

844.     Quantum theory of radiation of an excited atom placed near microresonant containing
 single photon wave packet: photon correlation properties.

V.V. Klimov, V.S. Letokhov, M. Ducloy.

Laser Physics 17, ¹7, 912-926 (2007).

 

 

Nanofabrication and nanoprocessing

 

644.     Selection of Particles by a Gradient Force in the Near Field of Laser Light.

V.V. Klimov, V.S. Letokhov

Pis'ma Zh. Eksp. Teor. Fiz. 59, ¹9, 582-585 (1994), [JETP Lett., 59, ¹9,

609-612 (1994)].

 

647.     Selective Sorting of Neutral Atoms and Molecules by the Gradient Dipole Force

in the Near Field of Laser Radiation.

V.V. Klimov, V.S. Letokhov.

Optics Comm. 110, 87-93 (1994).

 

648.     The Possibility of Nanolocal Reactions on Surface.
            Yu.E. Lozovik, S.P. Merkulova, S.K. Sekatskii, V.S. Letokhov.
            Phys.Letts. 189, 131-133 (1994).

 

661.     Trapping of Atoms in Near Field of Laser Radiation.
            V.V. Klimov, V.S. Letokhov.

            Pis'ma Zh.Eksp. Teor.Fiz. 61, 15-19 (1995) (in Russian).

 

670.     Particle Selection by Gradient Force in Near-Field of Laser Radiation.

            V.V. Klimov, V.S. Letokhov.

            Zh.Eksp. Teor.Fiz. 108, 91-104 (1995) [JETP 81(1), 49-55 (1995)].

 

673.     Laser Maxwell’s Demon.

            V.S. Letokhov.

            Contemporary Physics 36, ¹4, 235-243 (1995).

 

674.     Possibility of Selective Adsorption of Molecules on Modified Surface.
        
    Yu.E.
Lozovik, A.M. Popov, V.S. Letokhov.

            J. Phys. Chem. 99, 13480-13486 (1995).


838.     Femtosecond laser source of nanolocalized directed photoelectrons.

S.A. Aseyev, B.N. Mironov, S.V. Chekalin, V.S. Letokhov.

Appl. Phys. Lett. 89, 112513-…... (2006).

 

839.     Atom pin-hole camera with nanometer resolution.

V.I. Balykin, P.A. Borisov, V.S. Letokhov, P.N. Melentiev, S.N. Rudnev, A.P. Cherkun,
A.P. Akimenko, P.Yu. Apel, V.A. Skuratov.

Pis’ma Zh. Eksp. Teor. Fiz. 84(8), 544-547 (2006); [JETP Lett. 84(8), 466-469 (2006)].

 

846.     Atomic projection parallel fabrication of nanostructures.

V.I. Balykin, P.A. Borisov, V.S. Letokhov, P.N. Melentiev, S.N. Rudnev, A.P. Cherkun,
A.P. Akimenko, P.Yu. Apel, V.A. Skuratov.

Proceed. of Russ. Acad. of Sci. 72, ¹2, 224-228 (2008).

 

 

Spectroscopy of nanostructures

 

572.     Prospects of Laser Spectroscopy of Biomolecules with Nanometer Spatial Resolution.

            V.S. Letokhov.

In: Laser Spectroscopy IX ed. by M. Feld, J. Thomas, A. Mooradian (Proc. of the Ninth
Int. Laser Spectroscopy Conf., Bretton Woods, N.H., June 18-23, 1989) (Academic Press,
Boston, 1989), pp. 494-499.

 

769.     Coherent Radiation Scattering by Resonant Nanostructures.

            V.V. Klimov, V.S. Letokhov.

            Phys. Rev. B62, ¹3, 1639-1642 (2000).

 

 

Applications of nanostructures

 

693.     Hard X-radiation Emitted by a Charged Particle Moving in a Carbon Nanotube.

            V.V. Klimov, V.S. Letokhov.

            Physics Letters A222, ¹6, 424-428 (1996).

 

699.     Mixed Electron-Nuclear Transitions in Multiply Charged Ions: Potentialities for

            X-gamma-Laser.

            V.S. Letokhov.

In: “X-ray Lasers 1996”, ed. by S. Svanberg and C.-G. Wahlström. Proceed. of 5th Intern.
Conf., Lund, Sweden, June 1996. Publ. of Inst. of Physics, Vol. 151 (Bristol, 1996), 483-490.

 

706.     Monochromatic g-radiation Emitted by a Relativistic Electron Moving in a Carbone

            Nanotube.

            V.V. Klimov, V.S. Letokhov.

            Phys. Letters A226, 244-252 (1997).

 

725.     Hard Directional X-Radiation Emitted by a Positron Moving in a Carbon Nanotube.

            V.V. Klimov, V.S. Letokhov.

            Physica Scripta 56, 480-486 (1997).

 

726a.   Hard Highly Directional X-Radiation Emitted by a Charged Particle Moving in a
Carbon Nanotube.

            V.V. Klimov, V.S. Letokhov.

            In: “Atomic Physics Methods in Modern Research”. Eds. K. Jungman, J. Kowalski,
            I.
Peinard, F. Trager (Berlin, Springer, 1997), 167-164.

 

735.     On the Possibility of Ultra-High Density WROM Based on the Using of Laser and
Corpuscular Beams.

V.S. Letokhov, S.K. Sekatskii.

Optics Comm. 147, ¹1-3, 19-25 (1998).