FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2014863957> ?p ?o ?g. }

• W2014863957 endingPage "377" @default.
• W2014863957 startingPage "345" @default.
• W2014863957 abstract "Abstract A review is given of studies on the time resolution of photobleaching of solvated (or trapped) electrons following excitation by a 20 ns Q-switched ruby laser pulse. Various transient and permanent bleaching effects are shown to evolve on distinct time scales ranging form nano-seconds to tenths-of-a-second. The systems studied were: photolytically produced hydrated electrons in liquid water at room temperature, γ-induced trapped electrons in a variety of aqueous and organic glasses at 77 K and γ- or additively produced F-centre electrons in KBr and KI crystals at room temperature and 77 K. A number of effects were observed which are pertinent to a basic understanding of the nature and origin of the optical absorption bands of solvated electrons. They are also pertinent to the interpretations to be placed on photobleaching and photoconductivity data under “steady-state”, low intensity illumination. In addition to transient and immediate bleaching effects arising directly from photoexcitation, there are important contributions to the overall net bleaching of trapped electrons in glasses which take place up to 1 s after the light pulse. These apparently arise from incipient but latent electron states or from a delayed response of the medium to multiple excitations (and de-excitation or retrapping) of et-. In aqueous glasses transient species which absorb in the I.R. (1152 nm) are observed to arise from photoexcitation of et− at 694 nm. Transient bleaching was seen for K2CO3 and NaClO4 aqueous glasses at 77 K but only at the wavelength of excitation. For LiCl glasses at 77 K and F-centres at ≈ 295 K, bleaching of the whole band occurred and indicated the formation of long-lived photoexcited states. For eaq− in liquid water the ground state is repopulated too rapidly to observe non-linear absorption, consequently the excited state (whether bound or free) has a lifetime less than 3–5 ps. The absorption band of et− in α-methylterahydrofuran glasses at 77 K must be “heterogeneous” on its high energy tail since none of the permanent bleaching at 694 nm is accompanied by bleaching on the same time scale at 633 or 442 nm. Variations of the integrated Beer-Lambert absorption law are presented for use with high light intensities. The appropriate equations are developed to show how the absorbance at a monitoring wavelength changes as a result of concurrent intense illumination at another wavelength. It is also shown that for absorption bands which are heterogeneously broadened, due to the presence of underlying discrete bands, the extinction coefficients will be larger than those calculated on the basis of the band being homogeneous. When very narrow discrete bands exist the absorption spectrum observed is merely the profile of the population distribution of traps." @default.
• W2014863957 created "2016-06-24" @default.
• W2014863957 creator A5054490823 @default.
• W2014863957 creator A5063332285 @default.
• W2014863957 date "1974-12-01" @default.
• W2014863957 modified "2023-10-17" @default.
• W2014863957 title "Time-resolved photobleaching of solvated electron absorption bands" @default.
• W2014863957 cites W1972188647 @default.
• W2014863957 cites W1972595572 @default.
• W2014863957 cites W1975585003 @default.
• W2014863957 cites W1976153091 @default.
• W2014863957 cites W1977896124 @default.
• W2014863957 cites W1978229339 @default.
• W2014863957 cites W1982205180 @default.
• W2014863957 cites W1985290880 @default.
• W2014863957 cites W1985471149 @default.
• W2014863957 cites W1994649809 @default.
• W2014863957 cites W1995473701 @default.
• W2014863957 cites W1999108038 @default.
• W2014863957 cites W2000926311 @default.
• W2014863957 cites W2007060432 @default.
• W2014863957 cites W2008229955 @default.
• W2014863957 cites W2010322678 @default.
• W2014863957 cites W2015100774 @default.
• W2014863957 cites W2017570371 @default.
• W2014863957 cites W2019175440 @default.
• W2014863957 cites W2020506562 @default.
• W2014863957 cites W2020968250 @default.
• W2014863957 cites W2026812614 @default.
• W2014863957 cites W2027027575 @default.
• W2014863957 cites W2027681017 @default.
• W2014863957 cites W2028393466 @default.
• W2014863957 cites W2031479089 @default.
• W2014863957 cites W2032666619 @default.
• W2014863957 cites W2045598826 @default.
• W2014863957 cites W2050214647 @default.
• W2014863957 cites W2050334731 @default.
• W2014863957 cites W2050397956 @default.
• W2014863957 cites W2053318299 @default.
• W2014863957 cites W2053469550 @default.
• W2014863957 cites W2054203841 @default.
• W2014863957 cites W2055482629 @default.
• W2014863957 cites W2055665452 @default.
• W2014863957 cites W2059586846 @default.
• W2014863957 cites W2061528397 @default.
• W2014863957 cites W2064733132 @default.
• W2014863957 cites W2064767159 @default.
• W2014863957 cites W2069275691 @default.
• W2014863957 cites W2070538306 @default.
• W2014863957 cites W2070793106 @default.
• W2014863957 cites W2071022276 @default.
• W2014863957 cites W2078732198 @default.
• W2014863957 cites W2090159137 @default.
• W2014863957 cites W2149082317 @default.
• W2014863957 cites W2160977257 @default.
• W2014863957 cites W2295472543 @default.
• W2014863957 cites W2317116363 @default.
• W2014863957 cites W2318065680 @default.
• W2014863957 cites W2491960034 @default.
• W2014863957 cites W4239898938 @default.
• W2014863957 cites W81002507 @default.
• W2014863957 doi "https://doi.org/10.1016/0020-7055(74)90006-0" @default.
• W2014863957 hasPublicationYear "1974" @default.
• W2014863957 type Work @default.
• W2014863957 sameAs 2014863957 @default.
• W2014863957 citedByCount "16" @default.
• W2014863957 crossrefType "journal-article" @default.
• W2014863957 hasAuthorship W2014863957A5054490823 @default.
• W2014863957 hasAuthorship W2014863957A5063332285 @default.
• W2014863957 hasConcept C120665830 @default.
• W2014863957 hasConcept C121332964 @default.
• W2014863957 hasConcept C125287762 @default.
• W2014863957 hasConcept C147120987 @default.
• W2014863957 hasConcept C147789679 @default.
• W2014863957 hasConcept C159467904 @default.
• W2014863957 hasConcept C184651966 @default.
• W2014863957 hasConcept C185544564 @default.
• W2014863957 hasConcept C185592680 @default.
• W2014863957 hasConcept C31332276 @default.
• W2014863957 hasConcept C42296456 @default.
• W2014863957 hasConcept C66887884 @default.
• W2014863957 hasConcept C75473681 @default.
• W2014863957 hasConcept C91881484 @default.
• W2014863957 hasConceptScore W2014863957C120665830 @default.
• W2014863957 hasConceptScore W2014863957C121332964 @default.
• W2014863957 hasConceptScore W2014863957C125287762 @default.
• W2014863957 hasConceptScore W2014863957C147120987 @default.
• W2014863957 hasConceptScore W2014863957C147789679 @default.
• W2014863957 hasConceptScore W2014863957C159467904 @default.
• W2014863957 hasConceptScore W2014863957C184651966 @default.
• W2014863957 hasConceptScore W2014863957C185544564 @default.
• W2014863957 hasConceptScore W2014863957C185592680 @default.
• W2014863957 hasConceptScore W2014863957C31332276 @default.
• W2014863957 hasConceptScore W2014863957C42296456 @default.
• W2014863957 hasConceptScore W2014863957C66887884 @default.
• W2014863957 hasConceptScore W2014863957C75473681 @default.
• W2014863957 hasConceptScore W2014863957C91881484 @default.
• W2014863957 hasIssue "5-6" @default.

• next