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Optical electron

Yariv A 1997 Optical Electronics and Modern Communications 5th edn (New York Oxford University Press)... [Pg.2874]

Elliott C M, Derr D L, Matyushov D V and Newton M D 1998 Direct experimental comparison of the theories of thermal and optical electron-transfer studies of a mixed-valence dinuclear iron polypyridyl complex J. Am. Chem. [Pg.2995]

The market for optical fiber worldwide in 1992 was 2.8 billion corresponding to 10 million fiber kilometers (Mfk) (38). This can be broken down into the U.S. market (3.7 Mfk), the rest of North America (0.4 Mfk), northern Europe (4.1 Mfk), eastern Europe (2.6 Mfk), the Pacific Rim (2.8 Mfk), and elsewhere (0.3 Mfk). Most of the optical fiber is manufactured by only a few companies, the largest of which are AT T and Coming. Other producers include Alcatel, Eujikura, Eurakawa, Northern Telecom, Pirelli, and Sumitomo. The market for optical fibers is projected to reach 3.5 biUion by 1998. In addition, according to ElectroniCast (San Mateo, Ca.), the total market for passive optical components, optical electronics, connectors, and fiber-optic cable is predicted to increase from 1.76 billion (U.S.) in 1992 to over 4 billion in 1997, and 10 billion by 2002. [Pg.260]

Another growing apphcation that overlaps the electrically functional area is the use of transparent conductive coatings or tin oxide, indium—tin oxide, and similar materials in photovoltaic solar ceUs and various optic electronic apphcations (see Photovoltaic cells). These coatings are deposited by PVD techniques as weU as by spray pyrolysis, which is a CVD process. [Pg.51]

Griivimat SHC 502 Gravimetric Du.st Concentration Measuring System. Operating instructions. SICK ACi Waldkirch, Germany Erwin Sick Optic Electronic Lrd. [Pg.1314]

Optical particle counter An optical-electronic instrument for measuring the numbei" of airborne particles in different size ranges. [Pg.1463]

Leuchtelektron, n. emitting electron, optical electron photo-electron, leuchten, v.t. give light, shine, glow, luminesce. [Pg.276]

Ceric Oxide (Cerium Dioxide, Cerium Oxide, Ceria). CeOj, mw 172.13, white powd, mp ca 2600°, d 7.132g/cc at 23°. Sol in coned sulfuric and nitric acids, insol in dil acids and w. Prepn is by dissolving CeCOj in 16N HNOa contg 3% H202 and then evapg off the nitrate soln followed by thermal decompn. The yield is 97.6% of 99.8% pure Ce02, The oxide is used in optics, electronics, as a diluent in nuclear fuels (as... [Pg.450]

Reorganisation energies of optical electron transfer processes. R. D. Cannon, Adv. Inorg. Chem. Radiochem., 1978, 21 179-230 (155). [Pg.27]

Valette-Hamelin approach,67 and other similar methods 24,63,74,218,225 (2) mass transfer under diffusion control with an assumption of homogeneous current distribution73 226 (3) adsorption of radioactive organic compounds or of H, O, or metal monolayers73,142,227 231 (4) voltammetry232,233 and (5) microscopy [optical, electron, scanning tunneling microscopy (STM), and atomic force microscopy (AFM)]234"236 as well as a number of ex situ methods.237 246... [Pg.42]

Coatings are used on a large scale in many production applications in optics, electronics, optoelectronics, tools, wear, and erosion and others. In the case of electronics and optoelectronics, practically all CVD applications are in the form of coatings. [Pg.109]

Reorganization Energies of Optical Electron Transfer Processes R. D. Cannon... [Pg.440]

Blasse G (1991) Optical Electron Transfer Between Metal Ions and its Consequences. 76 153-188... [Pg.242]

Noble metal nanoparticles dispersed in insulating matrices have attracted the interest of many researchers fromboth applied and theoretical points of view [34]. The incorporation of metallic nanoparticles into easily processable polymer matrices offers a pathway for better exploitation of their characteristic optical, electronic and catalytic properties. On the other hand, the host polymers can influence the growth and spatial arrangement of the nanoparticles during the in situ synthesis, which makes them convenient templates for the preparation of nanoparticles of different morphologies. Furthermore, by selecting the polymer with certain favorable properties such as biocompatibiHty [35], conductivity [36] or photoluminescence [37], it is possible to obtain the nanocomposite materials for various technological purposes. [Pg.136]

Dconen, M, Sharonov, A, Tkachenko, N, and Lemmetyinen (1993), Adv. Mater. Optics Electron., 2,... [Pg.208]

Optical Electron Transfer Between Metal Ions... [Pg.155]

See other pages where Optical electron is mentioned: [Pg.288]    [Pg.2985]    [Pg.138]    [Pg.392]    [Pg.47]    [Pg.60]    [Pg.120]    [Pg.200]    [Pg.362]    [Pg.211]    [Pg.191]    [Pg.249]    [Pg.239]    [Pg.153]    [Pg.294]    [Pg.670]   
See also in sourсe #XX -- [ Pg.16 ]



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Characterization by optical and electron microscopy

Conductivity, electronic optical

ELECTRONIC AND OPTICAL APPLICATIONS

Electron Localization and Femtosecond Nonlinear Optical Responses in Liquids

Electron optical column

Electron optical components

Electron optics

Electron optics

Electron optics of STEM

Electron paramagnetic resonance optical

Electron transfer optical

Electron-excitation states optically forbidden

Electron-optical system

Electron-transfer reaction optical process

Electronic (optical) absorption spectroscopy

Electronic Optical Nonlinearities

Electronic Spectra, Optical Rotatory Dispersion-Circular Dichroism

Electronic and Linear Optical properties of Neutral Oligothiophenes

Electronic and Optical Materials

Electronic and optical aspects

Electronic band structure optical properties

Electronic molecular nonlinear optical

Electronic molecular nonlinear optical determination

Electronic molecular nonlinear optical susceptibility

Electronic nonlinear optical applications

Electronic optical activity

Electronic origin, nonlinear optical

Electronic origin, nonlinear optical structures

Electronic response, optical properties

Electronic structure optical spectra

Electronic, Magnetic, and Optical properties

Electronic, electromagnetic, and optical properties

Electrons optical excitations

Electrons optical transitions

Electrons, optical detrapping

Geometry, electronic structure and optical spectrum of azocompounds

Hydrated electron optical production

Integration of Gold Nanoparticles Application in Optics and Electronics

Japan Electron Optics Laboratory

Microscope: electron 221 image optical

Mixed-valence compounds optical electron transfer

Nanocomposites optical/electronic characteristics

New Optical Rewritable Electronic Paper

OPTICAL AND ELECTRONIC PROPERTIES OF SOLIDS

Optical Constants and Electronic Structure

Optical Electron Transfer (Intervalence Transitions)

Optical absorption electron, liquid helium

Optical absorption electrons

Optical and Electron Microscopy

Optical and Electronic Properties

Optical and electron paramagnetic

Optical and thermal electron transfer

Optical electron polarization

Optical electron transfer energy

Optical electron-transfer process

Optical electronic spectroscopy

Optical microscopy compared with electron

Optical microscopy compared with electron microscop

Optical properties, spectroscopy transitions, electronic

Optical scanning electron microscopy

Optical sensors, electronic nose technology

Optical techniques electron energy loss spectroscopy

Optically forbidden electronic states

Optics, electron microscopes

Postscript Energy Terms in Optical and Thermal Electron Transfer

Reorganization Energies of Optical Electron Transfer Processes

Reorganization Energies of Optical Electron Transfer Processes R. D. Cannon

Reorganization energy of optical electron

Sensor electron optical

Solvated electron optical absorption

Spectra, electronic absorption optical

Transmission electron basic optics

Transmission electron microscopy optics compared with optical

Trapped electron optical absorption band

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