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Quantum electronics

Even newer technologies that allow device fabrication on an atomic scale have made possible exotic devices such as highly efficient heterojunction lasers, single electron transistors, and various quantum confinement devices that act as artificial atoms in which the energy levels can be controlled by design. [Pg.11]

Schubert M and Wilhiemi B 1986 Nonlinear Optics and Quantum Electronics (New York Wiley)... [Pg.1225]

Wang 0-S 1975 The stimulated Raman process Quantum Electronics vol 1A, ed H Rabin and 0 L Tang (New York Academic) pp 447-72... [Pg.1228]

Dadap J I, Hu X F, Russell N M, Ekerdt J G, Lowell J Kand Downer M C 1995 Analysis of second-harmonic generation by unamplified, high-repetition-rate, ultrashort laser pulses at Si(OOI) interfaces/ J. Selected Topics Quantum Electron 1 1145-55... [Pg.1302]

Wokosin D L, Centonze V, White J G, Armstrong D, Robertson G and Ferguson A I 1996 All-solid-state ultrafast lasers facilitate multiphoton excitation fluorescence imaging IEEE J. Sel. Top. Quantum Electron. 21051-65... [Pg.1674]

Pedersen J E and Keiding S R 1992 THz time-domain spectroscopy of non-polar liquids IEEE J. Quantum. Electron. 28 2518-22... [Pg.1991]

Valdmanis J A and Fork R L 1986 Design considerations for a femtosecond pulse laser balancing self phase modulation, group velocity dispersion, saturable absorption, and saturable gain IEEE J. Quantum. Electron. 22 112-18... [Pg.1991]

Treacy E B 1969 Optical pulse compression with diffraction gratings IEEE J. Quantum. Electron. 5 454-8... [Pg.1993]

Kuhl J and Heppner J 1986 Compression of femtosecond optical pulses with dielectric multilayer interferometers IEEE J. Quantum. Electron. 22 182-5... [Pg.1993]

Mollenauer L F, Gordon J P and Islam M N 1986 Soliton propagation in long fibers with periodically compensated loss IEEE J. Quantum. Electron. 22 157-73... [Pg.1994]

Kane D J and Terbino R 1993 Characterization of arbitrary femtosecond pulses using frequency-resolved optical gating IEEE J. Quantum. Electron. 29 571-9... [Pg.1994]

Diz A, Deumens E and Ohm Y 1990 Quantum electron-nuclear dynamics Chem. Phys. Lett. 166 203... [Pg.2329]

Brus L 1986 Zero-dimenslonal excltons In semiconductor clusters IEEE J. Quantum Electron. 22 1909... [Pg.2921]

Legay-Sommaire N and Legay F 1980 Observation of a strong vibrational population inversion by CO laser exoitation of pure solid oarbon monoxide IEEE J. Quantum Electron. 16 308-14... [Pg.3049]

The approximations defining minimal END, that is, direct nonadiabatic dynamics with classical nuclei and quantum electrons described by a single complex determinantal wave function constructed from nonoithogonal spin... [Pg.233]

The END trajectories for the simultaneous dynamics of classical nuclei and quantum electrons will yield deflection functions. For collision processes with nonspherical targets and projectiles, one obtains one deflection function per orientation, which in turn yields the semiclassical phase shift and thus the scattering amplitude and the semiclassical differential cross-section... [Pg.236]

Quantum efficiencies Quantum efficiency Quantum electronics Quantum fluids Quantum mechanics Quantum size effect Quantumwell... [Pg.834]

S. Sato andH. Inaba, Optical and Quantum Electronics 2 1—16 (1996). [Pg.213]

A. Yansc, Quantum Electronics, 3rd ed., John Wiley Sons, Inc., New York, 1989. [Pg.386]

C. H. Townes (Massachusetts Institute of Technology), and N. G. Basov and A. M. Prokhorov (Moscow) fundamental work in the field of quantum electronics, which led to the construction of oscillators and amplifiers based on the maser-laser-principle. [Pg.1302]

Townes s academic life continued. He served as provost of MIT from 1961 to 1966. In 1964, Townes received the Nobel Prize in physics for work in quantum electronics leading to construction of oscillators and amplifiers based on the maser-laser principle. He was named university professor at the University of California-Berkeley in 1967. There he worked for more than 20 years in astrophysics. Ironically, this field is one of many that were transformed by die laser, and Townes often tised lasers in his subsequent research. [Pg.1143]

Tantalum and niobium are added, in the form of carbides, to cemented carbide compositions used in the production of cutting tools. Pure oxides are widely used in the optical industiy as additives and deposits, and in organic synthesis processes as catalysts and promoters [12, 13]. Binary and more complex oxide compounds based on tantalum and niobium form a huge family of ferroelectric materials that have high Curie temperatures, high dielectric permittivity, and piezoelectric, pyroelectric and non-linear optical properties [14-17]. Compounds of this class are used in the production of energy transformers, quantum electronics, piezoelectrics, acoustics, and so on. Two of... [Pg.1]

U. Lcmmer, Iniermiiioiuil Quantum Electronics Conference, Vol. 7, 1998 OSA Technical Digest series (Optical Society ol" America, Washington, DC, 1998) p. 135. [Pg.456]

A.I. Gubanov, Quantum-Electronic Theory of Amorphous Semi-Conductors, Izd. Akad. Nauk SSSR, Moscow-Leningrad, 1963. [Pg.298]

Byer, R., 1975, Treatise In Quantum Electronics, Academic Press, H. Rabin, C. Tang Eds, 587... [Pg.349]

Bennett, W.R. In Advanced Quantum Electronics Singer, J. Ed. Columbia... [Pg.19]

Sheik-Bahae, M., Said, A. A., Wei, T. H., Hagan, D. J. and Van Stryland, E. W. (1990) Sensitive measurement of optical nonlinearities using a single beam. IEEE J Quantum Electron., 26, 760-769. [Pg.167]

Ashkrn, A. (2000) History of optical trapping and manipulation of small-neutral particle, atoms, and molecules. IEEE J. Select. Topics Quantum Electron., 6, 841-856. [Pg.168]

Sheik-Bahae M, Hutchings DC, Hagan DJ, Van Stryland EW (1991) Dispersion of bound electronic nonlinear refraction in solids. IEEE J Quantum Electron 27 1296-1309... [Pg.144]

Sheik-Bahae M, Wang J, Van Stryland EW (1994) Nondegenerate optical Kerr-effect in semiconductors. IEEE J Quantum Electron 30 249-255... [Pg.144]

See other pages where Quantum electronics is mentioned: [Pg.1225]    [Pg.226]    [Pg.326]    [Pg.21]    [Pg.396]    [Pg.496]    [Pg.340]    [Pg.90]    [Pg.704]    [Pg.1143]    [Pg.444]    [Pg.491]    [Pg.341]    [Pg.232]    [Pg.187]    [Pg.349]    [Pg.290]    [Pg.188]    [Pg.40]    [Pg.662]   
See also in sourсe #XX -- [ Pg.355 ]

See also in sourсe #XX -- [ Pg.1262 ]



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Atomic Orbitals A Quantum Mechanical Description of Electrons Around the Nucleus

Atomic structure, quantum mechanics electron configurations

Carlo Quantum Methods for Electronic Structure

Core electrons, quantum Monte Carlo

Dynamics in the electron-nuclear quantum-classical mixed representation

Electron Densities for Molecular Quantum Similarity

Electron Spin A Fourth Quantum Number

Electron Spin Quantum Number (ms)

Electron Spin in Nonrelativistic Quantum Mechanics

Electron density quantum fluid dynamics

Electron impact ionization cross sections quantum mechanical

Electron quantum numbers and

Electron quantum tunneling

Electron quantum yield

Electron quantum-mechanical model

Electron scattering quantum chemistry

Electron scattering quantum chemistry (ESQC

Electron self-energy, quantum electrodynamics

Electron spin quantum

Electron spin quantum number

Electron transfer quantum electronic theories

Electron transfer quantum mechanical model

Electron transfer quantum mechanical theory

Electron transfer quantum mechanics

Electron transfer reactions quantum transition-state theory

Electron-positron virtual pairing electrodynamics, quantum

Electronic Quantum Size Effects

Electronic conductivity quantum wells

Electronic configuration principal quantum number

Electronic configuration quantum jumps

Electronic configuration quantum mechanical model

Electronic excitation quantum chemical calculations

Electronic excitation quantum yields

Electronic excitation quantum yields chemiluminescence

Electronic quantum exchange

Electronic quantum index

Electronic states elements of molecular quantum mechanics

Electronic states triatomic quantum reaction dynamics

Electronic states, quantum reaction dynamics

Electronic states, triatomic quantum reaction

Electronic structure quantum mechanics

Electronic structure quantum numbers

Electronic structure quantum-mechanical approach

Electronic structure, metals quantum free-electron theory

Electronics property quantum efficiency

Electrons Hall effect quantum

Electrons principal quantum number

Electrons quantum jumps

Electrons quantum mechanics

Electrons quantum numbers

Englman and A. Yahalom Quantum Reaction Dynamics for Multiple Electronic States

Further Concepts in Quantum Mechanics and their Application to Many-electron Atoms

General Aspects of Quantum Chemistry and Electronic Structure Calculations

Hot electron and hole cooling dynamics in quantum-confined

Many-electron quantum mechanics

One-Electron Atom Quantum Numbers

Orbital quantum number multi-electron species

Quantum Chemical Calculations of Electronic Excitation

Quantum Chemical Treatment of Electronic Couplings in DNA Fragments

Quantum Electrodynamics in One- and Two-Electron High-Z Ions

Quantum Mechanical Many-Electron Problem

Quantum Mechanics of Electron Transfer

Quantum Model of Bonding Electrons in Crystal

Quantum Model of Free Electrons in Crystal

Quantum Model of Quasi-Free Electrons in Crystals

Quantum Model of Tight-Binding Electrons in Crystal

Quantum Numbers and Energies of Electrons

Quantum Theory and the Electronic Structure of Atoms

Quantum Theory of Free Electrons

Quantum chemistry electronic structure representation

Quantum confinement of electronic states

Quantum confinement of electrons

Quantum dots electron absorption spectroscopy

Quantum dots electron beam lithography

Quantum dots electronic properties

Quantum electronic properties

Quantum electronic theory

Quantum free-electron theory

Quantum free-electron theory, constant-potential

Quantum mechanical calculations electronic structure

Quantum mechanical calculations of electron

Quantum mechanical model electron spin

Quantum mechanical treatments of electron

Quantum mechanical treatments of electron transfer processes

Quantum mechanics electron cloud representation

Quantum mechanics electron correlation methods

Quantum mechanics electron density diagram

Quantum mechanics electron spin

Quantum mechanics electronic

Quantum mechanics electronic energy

Quantum mechanics intermolecular interaction, electronic

Quantum mechanics methods electronic structure-based explicit

Quantum mechanics multiple states electronic structure

Quantum mechanics of many-electron systems

Quantum molecular electronics

Quantum number, azimuthal electron-spin

Quantum numbers of electrons

Quantum reaction dynamics, electronic

Quantum reaction dynamics, electronic analysis

Quantum reaction dynamics, electronic states adiabatic representation

Quantum reaction dynamics, electronic states equation

Quantum reaction dynamics, electronic states nuclear motion Schrodinger equation

Quantum theory of electron-transfer reactions

Quantum-mechanical electronic

Radiationless electron transfer, quantum

Radiationless electron transfer, quantum mechanical treatment

Semiconductor quantum dots electron-phonon

Simple quantum chemical models of electronic excitation

Spin quantum number multi-electron species

The Electron-Spin Quantum Number

The Quantum Chemistry of Loosely-Bound Electrons

The Quantum-Classical Density Operator for Electronically Excited Molecular Systems

The independent-electron model as a quantum field theory

The quantum free-electron gas

Valence electrons computational quantum

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