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Contacts injecting

Akuetey G, Hirsch J (1991) Contact-injected currents in polyvinylcarbazole. Phil Mag B 63 389... [Pg.64]

Some types of the polymers were investigated in detail. The photoconductivity of polyethylene with quantum efficiency 10 5-10 10 is caused by impurities, Schottky type contact injection, and hole transport [82,83], The crystallinity increase is accompanied by a photocurrent increase. There is no clear correlation between the chemical structure and the photocurrent. [Pg.25]

Exposure route The avenue by which a chemical comes into contact with an organism, e.g. inhalation, ingestion, dermal contact, injection, etc. (USEPA, 1997b). [Pg.396]

Fig. 5.2. A chart showing the work function of several metals (a) [81] and the HOMO/LUMO levels of several organic semicondnctors relative to the vacuum level (b) [82] [83] in eV. Theoretically, in n-type devices we want to inject electrons and therefore wonld expect to see the best performance using electrodes whose work function lines up with the LUMO, and for p-type contacts (injecting holes) hned up with the the HOMO. In practice, noble metals appear to work best for most material systems, (c) Contact dipoles caused by chemical interactions with the metal surface, dopants, and contaminants can vary the energy level/contact offsets-those seen by [82] [83] are shown. On this diagram, these offsets appear as a shift in the vacuum level. Note that the effective energy levels for organic semiconductors wiU differ on different surfaces these are both measured deposited in a thin layer on gold. Fig. 5.2. A chart showing the work function of several metals (a) [81] and the HOMO/LUMO levels of several organic semicondnctors relative to the vacuum level (b) [82] [83] in eV. Theoretically, in n-type devices we want to inject electrons and therefore wonld expect to see the best performance using electrodes whose work function lines up with the LUMO, and for p-type contacts (injecting holes) hned up with the the HOMO. In practice, noble metals appear to work best for most material systems, (c) Contact dipoles caused by chemical interactions with the metal surface, dopants, and contaminants can vary the energy level/contact offsets-those seen by [82] [83] are shown. On this diagram, these offsets appear as a shift in the vacuum level. Note that the effective energy levels for organic semiconductors wiU differ on different surfaces these are both measured deposited in a thin layer on gold.
Conwell, E.M., and M.W. Wu. 1997. Contact injection into polymer light-emitting diodes. Appl Phys Lett 70 1867-1869. [Pg.833]

The Au on mica substrate is ohmic for hole injection into coated layers of Tro/Polycarbonate when measured a day after coating. However, when Au is evaporated on the same molecularly doped polymer (MDP) transport layer it is found that the injection efficiency is a strong function of the deposition conditions. For Au evaporated at normal deposition rates (2-10 A/ sec) the contact injection behavior evolves from emission limited to oh c as a systematic function of time and temperature. [Pg.116]

Aquifer/oil/water contact Injection not deep in aquifer or far below oil/water contact Additional retention losses in transport to oil leg... [Pg.316]

The vacancy is very mobile in many semiconductors. In Si, its activation energy for diffusion ranges from 0.18 to 0.45 eV depending on its charge state, that is, on the position of the Fenni level. Wlrile the equilibrium concentration of vacancies is rather low, many processing steps inject vacancies into the bulk ion implantation, electron irradiation, etching, the deposition of some thin films on the surface, such as Al contacts or nitride layers etc. Such non-equilibrium situations can greatly affect the mobility of impurities as vacancies flood the sample and trap interstitials. [Pg.2888]

Venturi scmbbers can be operated at 2.5 kPa (19 mm Hg) to coUect many particles coarser than 1 p.m efficiently. Smaller particles often require a pressure drop of 7.5—10 kPa (56—75 mm Hg). When most of the particulates are smaller than 0.5 p.m and are hydrophobic, venturis have been operated at pressure drops from 25 to 32.5 kPa (187—244 mm Hg). Water injection rate is typicaUy 0.67—1.4 m of Hquid per 1000 m of gas, although rates as high as 2.7 are used. Increasing water rates improves coUection efficiency. Many venturis contain louvers to vary throat cross section and pressure drop with changes in system gas flow. Venturi scmbbers can be made in various shapes with reasonably similar characteristics. Any device that causes contact of Hquid and gas at high velocity and pressure drop across an accelerating orifice wiU act much like a venturi scmbber. A flooded-disk scmbber in which the annular orifice created by the disc is equivalent to a venturi throat has been described (296). An irrigated packed fiber bed with performance similar to a... [Pg.410]

Injection-molded articles can be decorated by in-mold labeling or by post-mold decoration. In the former method, printed film is inserted into the mold cavity before injection. The plastic forms an intimate contact with the graphic material. Post-mold decoration includes hot stamping, dry offset printing, and decal printing. [Pg.454]

Species origin tests, used to determine whether the specimen is human or from another source, are immunological in nature. Host animals, usually rabbits, are injected with protein from another species. The animal creates antibodies to the unknown material. Semm from the host animal, containing species (human, bovine, equine, canine, etc) specific antibodies, is tested against a dilute solution of blood (antigens) collected as evidence. A positive reaction is determined by a visible band where the antibodies and antigens come into contact. [Pg.487]

The third characteristic of interest grows directly from the first, ie, the high thermal conductance of the heat pipe can make possible the physical separation of the heat source and the heat consumer (heat sink). Heat pipes >100 m in length have been constmcted and shown to behave predictably (3). Separation of source and sink is especially important in those appHcations in which chemical incompatibilities exist. For example, it may be necessary to inject heat into a reaction vessel. The lowest cost source of heat may be combustion of hydrocarbon fuels. However, contact with an open flame or with the combustion products might jeopardize the desired reaction process. In such a case it might be feasible to carry heat from the flame through the wall of the reaction vessel by use of a heat pipe. [Pg.512]

Early injection lasers were small rectangular parallelepipeds made by cutting a wafer of GaAs. Feedback was provided by mirrors polished on two edges or by cleaving. The wafer had ap—n junction incorporated into it and broad area or stripe contacts were provided. Laser stmctures have since evolved to satisfy a wide range of appHcation specific requirements. [Pg.133]

Wettabihty is defined as the tendency of one fluid to spread on or adhere to a soHd surface (rock) in the presence of other immiscible fluids (5). As many as 50% of all sandstone reservoirs and 80% of all carbonate reservoirs are oil-wet (10). Strongly water-wet reservoirs are quite rare (11). Rock wettabihty can affect fluid injection rates, flow patterns of fluids within the reservoir, and oil displacement efficiency (11). Rock wettabihty can strongly affect its relative permeabihty to water and oil (5,12). When rock is water-wet, water occupies most of the small flow channels and is in contact with most of the rock surfaces as a film. Cmde oil does the same in oil-wet rock. Alteration of rock wettabihty by adsorption of polar materials, such as surfactants and corrosion inhibitors, or by the deposition of polar cmde oil components (13), can strongly alter the behavior of the rock (12). [Pg.188]

Precipitate formation can occur upon contact of iajection water ions and counterions ia formation fluids. Soflds initially preseat ia the iajectioa fluid, bacterial corrosioa products, and corrosion products from metal surfaces ia the iajectioa system can all reduce near-weUbore permeability. Injectivity may also be reduced by bacterial slime that can grow on polymer deposits left ia the wellbore and adjacent rock. Strong oxidising agents such as hydrogen peroxide, sodium perborate, and occasionally sodium hypochlorite can be used to remove these bacterial deposits (16—18). [Pg.189]

The substantial decrease of polyacrylamide solution viscosity in mildly saline waters can be uti1i2ed to increase injection rates. A quaternary ammonium salt polymer can be added to the polyacrylamide solution to function as a salt and reduce solution viscosity (144). If the cationic charge is in the polymer backbone and substantially shielded from the polyacrylamide by steric hindrance, formation of an insoluble interpolymer complex can be delayed long enough to complete polyacrylamide injection. Upon contacting formation surfaces, the quaternary ammonium salt polymer is adsorbed reducing... [Pg.192]

Toxicology. Isoquinoline is a poison when ingested or injected intraperitoneally. Even in cases of skin contact it is moderately toxic. As in the case of quinoline, its vapors are irritating to the eyes, nose, and throat. Exposure causes headaches, dizziness, and nausea. Rapid absorption through the skin makes it a dangerous chemical. Its toxicity is oral LD q (i t)> mg/kg, and dermal LD q (rabbit), 590 mg/kg (65,66,182,183). [Pg.398]

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See also in sourсe #XX -- [ Pg.39 , Pg.41 , Pg.42 , Pg.49 ]



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