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Light excited electrons

FAAS Flame atomic absorption spectroscopy the flame atomizes metals in solutions. Once in the gas phase, the atoms absorb UV-vis light, exciting electrons to higher energy levels. The amount of light absorbed is used to determine the metal concentration. [Pg.131]

All the above-considered photoelectrochemical phenomena are based on the transition of light-excited electrons into a localized state in the solution, namely at the energy levels associated with individual ions or molecules. However, the phototransition is also possible when the electrons pass into a qualitatively different delocalized state in the solution it is this type of phototransition that represents photoemission (Barker et al, 1966). The emitted delocalized electron in the solution is then thermalized and localized to form a solvated (hydrated in aqueous solution) electron. The energy level, which corresponds to the solvated electron, lies below the bottom of the band of permitted delocalized states in the solution. Finally, the electron may pass from the solvated state to an even lower local energy level associated with an electron acceptor in the solution (see Fig. 30). [Pg.310]

The depletion layer profile on undoped a-Si H can be obtained by transient photoconductivity. A pulse of light excites electron-hole pairs very near the contact. As in the time-of-fiight experiment, holes are immediately collected by the contact and electrons drift down the internal field of the depletion layer, giving transient conductivity of... [Pg.328]

In each of the two photosystems, the primary step is transfer of a light-excited electron from a reaction center (P680 or P700) into an electron transport chain. [Pg.1158]

Silver bromide is a semiconductor. Absorbed light excites electrons in the conduction band and electron holes in the valence band. The holes oxidize bromide ions to traces of bromine that are dissolved in the gelatine layer. The free electrons reduce silver ions to silver atoms that form the catalytically active clusters in the halide crystallites. The reactions are ... [Pg.366]

The general scheme of a QDSC device is similar to the DSC concept. Light excites electron-hole pairs in the QDs. The electrons are injected into nanostructured Ti02 electrode (photosensitization), and they are transported to the transparent conductive oxide electrode. The holes are injected into the liquid or solid electrolyte which acts as a hole-transporting medium. The resulting holes are transported to the counterelectrode, where the oxidized... [Pg.1756]

One of the most interesting features of the Raman spectmm is its dependence on tire incident light frequency, coj. When Wj is on resonance with the excited electronic state, the scattering process closely resembles a process of absorption followed by emission. However, as Uj is detuned from resonance there are no longer... [Pg.250]

As described at the end of section Al.6.1. in nonlinear spectroscopy a polarization is created in the material which depends in a nonlinear way on the strength of the electric field. As we shall now see, the microscopic description of this nonlinear polarization involves multiple interactions of the material with the electric field. The multiple interactions in principle contain infomiation on both the ground electronic state and excited electronic state dynamics, and for a molecule in the presence of solvent, infomiation on the molecule-solvent interactions. Excellent general introductions to nonlinear spectroscopy may be found in [35, 36 and 37]. Raman spectroscopy, described at the end of the previous section, is also a nonlinear spectroscopy, in the sense that it involves more than one interaction of light with the material, but it is a pathological example since the second interaction is tlirough spontaneous emission and therefore not proportional to a driving field... [Pg.252]

Surface photochemistry can drive a surface chemical reaction in the presence of laser irradiation that would not otherwise occur. The types of excitations that initiate surface photochemistry can be roughly divided into those that occur due to direct excitations of the adsorbates and those that are mediated by the substrate. In a direct excitation, the adsorbed molecules are excited by the laser light, and will directly convert into products, much as they would in the gas phase. In substrate-mediated processes, however, the laser light acts to excite electrons from the substrate, which are often referred to as hot electrons . These hot electrons then interact with the adsorbates to initiate a chemical reaction. [Pg.312]

In light of tire tlieory presented above one can understand tliat tire rate of energy delivery to an acceptor site will be modified tlirough tire influence of nuclear motions on tire mutual orientations and distances between donors and acceptors. One aspect is tire fact tliat ultrafast excitation of tire donor pool can lead to collective motion in tire excited donor wavepacket on tire potential surface of tire excited electronic state. Anotlier type of collective nuclear motion, which can also contribute to such observations, relates to tire low-frequency vibrations of tire matrix stmcture in which tire chromophores are embedded, as for example a protein backbone. In tire latter case tire matrix vibration effectively causes a collective motion of tire chromophores togetlier, witliout direct involvement on tire wavepacket motions of individual cliromophores. For all such reasons, nuclear motions cannot in general be neglected. In tliis connection it is notable tliat observations in protein complexes of low-frequency modes in tlie... [Pg.3027]

Rapid e / h recombination, the reverse of equation 3, necessitates that D andM be pre-adsorbed prior to light excitation of the Ti02 photocatalyst. In the case of a hydrated and hydroxylated Ti02 anatase surface, hole trapping by interfacial electron transfer occurs via equation 6 to give surface-bound OH radicals (43,44). The necessity for pre-adsorbed D andM for efficient charge carrier trapping calls attention to the importance of adsorption—desorption equihbria in... [Pg.403]

Spectral Sensitization. Photographic silver haHde emulsions ate active with light only up to about 500 nm. However, theh sensitivity can be extended within the whole visible and neat-H spectral region up to about 1200—1300 nm. This is reached by the addition of deeply colored dyes that transfer excited electrons or excitation energy to the silver haHde. [Pg.496]

In photoluminescence one measures physical and chemical properties of materials by using photons to induce excited electronic states in the material system and analyzing the optical emission as these states relax. Typically, light is directed onto the sample for excitation, and the emitted luminescence is collected by a lens and passed through an optical spectrometer onto a photodetector. The spectral distribution and time dependence of the emission are related to electronic transition probabilities within the sample, and can be used to provide qualitative and, sometimes, quantitative information about chemical composition, structure (bonding, disorder, interfaces, quantum wells), impurities, kinetic processes, and energy transfer. [Pg.29]


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See also in sourсe #XX -- [ Pg.196 ]




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Electronic excited

Electronical excitation

Electronics, light

Electrons excitation

Electrons light

Electrons, excited

Excitation light

Light electron excitation

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