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Dopants films

Room temperature Scm CSA dopant film cast from ffi-cresol 400 (11)... [Pg.273]

CH3SO3H/ acetic acid dopant film cast 60 (5)... [Pg.273]

Several studies from the Shimidzu group described a CP "membrane which they ultimately utilized as an ion exchanger for deionization of water [1032-1034]. This comprised a P(Py) with a polymeric ("polyelectrolyte") dopant, poly(vinyl sulfate) (PVS). This CP/dopant film used in the conventional manner, i.e. as an immobilized film on a solid metal substrate electrode. Although not strictly a membrane, we discuss this here because its ion exchange properties can also be used in similar systems fashioned into membrane form, and because nearly all the titles of the publications dealing with such CP ion exchange electrodes have, erroneously it may be contended, the word "membrane" in them. [Pg.638]

PPQs possess a stepladder stmcture that combines good thermal stabiUty, electrical insulation, and chemical resistance with good processing characteristics (81). These properties allow unique appHcations in the aerospace and electronics industries (82,83). PPQ can be made conductive by the use of an electrochemical oxidation method (84). The conductivities of these films vary from 10 to 10 S/cm depending on the dopant anions, thus finding appHcations in electronics industry. Similarly, some thermally stable PQs with low dielectric constants have been produced for microelectronic appHcations (85). Thin films of PQs have been used in nonlinear optical appHcations (86,87). [Pg.537]

Diffusion. Another technique for modifying the electrical properties of siUcon and siUcon-based films involves introducing small amounts of elements having differing electrical compositions, dopants, into substrate layers. Diffusion is commonly used. There are three ways dopants can be diffused into a substrate film (/) the surface can be exposed to a chemical vapor of the dopant at high temperatures, or (2) a doped-oxide, or (J) an ion-implanted layer can be used. Ion implantation is increasingly becoming the method of choice as the miniaturization of ICs advances. However, diffusion is used in... [Pg.349]

Both anatase and mtile are broad band gap semiconductors iu which a fiUed valence band, derived from the O 2p orbitals, is separated from an empty conduction band, derived from the Ti >d orbitals, by a band gap of ca 3 eV. Consequendy the electrical conductivity depends critically on the presence of impurities and defects such as oxygen vacancies (7). For very pure thin films, prepared by vacuum evaporation of titanium metal and then oxidation, conductivities of 10 S/cm have been reported. For both siugle-crystal and ceramic samples, the electrical conductivity depends on both the state of reduction of the and on dopant levels. At 300 K, a maximum conductivity of 1 S/cm has been reported at an oxygen deficiency of... [Pg.121]

Zinc compounds are generally colorless unless the other component, eg, chromate, is colored. The lack of color of most zinc compounds in visible light is a great advantage in that they do not color paint films, plastics, mbber, cosmetics, etc. However, when excited by various types of radiation and at various temperatures, zinc oxide, sulfide, selenide [1315-09-9], and related compounds exhibit luminescence, ie, they emit colored light (see Luminescent materials). Zinc-based phosphors can be produced in many colors, depending upon the added dopants. They are used in television tubes, luminescent glasses, and various specialty products. [Pg.419]

Film CAS Registry Number Growth method Possible dopants Oxidizing color shift References... [Pg.158]

Electrochemical polymeriza tion of heterocycles is useful in the preparation of conducting composite materials. One technique employed involves the electro-polymerization of pyrrole into a swollen polymer previously deposited on the electrode surface (148—153). This method allows variation of the physical properties of the material by control of the amount of conducting polymer incorporated into the matrix film. If the matrix polymer is an ionomer such as Nation (154—158) it contributes the dopant ion for the oxidized conducting polymer and acts as an effective medium for ion transport during electrochemical switching of the material. [Pg.39]

Conducting polymer composites have also been formed by co-electrodeposition of matrix polymer during electrochemical polymerization. Because both components of the composite are deposited simultaneously, a homogenous film is obtained. This technique has been utilized for both neutral thermoplastics such as poly(vinyl chloride) (159), as well as for a large variety of polyelectrolytes (64—68, 159—165). When the matrix polymer is a polyelectrolyte, it serves as the dopant species for the conducting polymer, so there is an intimate mixing of the polymer chains and the system can be appropriately termed a molecular composite. [Pg.39]

The analytical techniques covered in this chapter are typically used to measure trace-level elemental or molecular contaminants or dopants on surfaces, in thin films or bulk materials, or at interfaces. Several are also capable of providing quantitative measurements of major and minor components, though other analytical techniques, such as XRF, RBS, and EPMA, are more commonly used because of their better accuracy and reproducibility. Eight of the analytical techniques covered in this chapter use mass spectrometry to detect the trace-level components, while the ninth uses optical emission. All the techniques are destructive, involving the removal of some material from the sample, but many different methods are employed to remove material and introduce it into the analyzer. [Pg.527]


See other pages where Dopants films is mentioned: [Pg.63]    [Pg.273]    [Pg.273]    [Pg.450]    [Pg.489]    [Pg.63]    [Pg.273]    [Pg.273]    [Pg.450]    [Pg.489]    [Pg.1827]    [Pg.2414]    [Pg.348]    [Pg.203]    [Pg.392]    [Pg.248]    [Pg.525]    [Pg.357]    [Pg.158]    [Pg.41]    [Pg.43]    [Pg.45]    [Pg.36]    [Pg.374]    [Pg.52]    [Pg.56]    [Pg.263]    [Pg.449]    [Pg.182]    [Pg.219]    [Pg.124]    [Pg.126]    [Pg.128]    [Pg.198]    [Pg.273]    [Pg.435]    [Pg.219]    [Pg.355]    [Pg.33]    [Pg.69]    [Pg.139]   
See also in sourсe #XX -- [ Pg.81 ]




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