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Spectral dependencies of the quantum yield of photochemical processes on the surface of nano/micro-particulates of wide-band-gap metal oxides. IV. Theoretical modeling of the activity and selectivity of semiconductor photocatalysts with inclusion of a subsurface electric field in the space charge region. / Emeline, A. V.; Frolov, A. V.; Ryabchuk, V. K.; Serpone, N.

в: Journal of Physical Chemistry B, Том 107, № 29, 21.07.2003, стр. 7109-7119.

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@article{d4de355cd2d549fbb685fd8f81a55071,
title = "Spectral dependencies of the quantum yield of photochemical processes on the surface of nano/micro-particulates of wide-band-gap metal oxides. IV. Theoretical modeling of the activity and selectivity of semiconductor photocatalysts with inclusion of a subsurface electric field in the space charge region",
abstract = "In an earlier study (Emeline, A.V.; Ryabchuk, V.K.; Serpone, N.J. Phys. Chem. B 1999, 103, 1316) we reported the solution to the continuity equation in which we neglected electric field effects and obtained expressions for the concentrations of the charge carriers at the surface (ns), for the quantum yield (φ) of a photochemical surface redox reaction, together with an expression for the selectivity of the photocatalyst. Various considerations led us to infer and predict wavelength-dependent phenomena (quantum yields and selectivity), which were later confirmed by experimental results (Emeline, A. V.; Serpone, N. J. Phys. Chem. B 2002, 106, 12221). In this article we revisit the continuity equation but include a subsurface electric field (E) in the space charge region of the semiconductor (or dielectric) photocatalyst to assess the effect that the electric field has on the activity and selectivity of the photocatalyst. The solution to the continuity equation yields very complex expressions for ns and for φ. Nonetheless, several cases are considered which simplify the expressions. Taking E = 0, the expression for the quantum yield transforms into the identical equation obtained earlier. Some of the predictions from the expressions obtained herein also find experimental verification from considerations, for example, of the quantum yields of photoadsorption of dioxygen and dihydrogen on TiO2 particles. The agreement between the predicted spectral behavior of the ratio γ = [es]/[hs] against wavelength with the spectral dependence of φO2/φH2 is remarkable. Another no less significant conclusion from the theoretical modeling results is that a mismatch between the experimental spectral dependence of the quantum yield and the corresponding absorption band may be an indicator of the existence of a space charge region in the solid photocatalyst.",
author = "Emeline, {A. V.} and Frolov, {A. V.} and Ryabchuk, {V. K.} and N. Serpone",
year = "2003",
month = jul,
day = "21",
language = "English",
volume = "107",
pages = "7109--7119",
journal = "Journal of Physical Chemistry B",
issn = "1520-6106",
publisher = "American Chemical Society",
number = "29",

}

RIS

TY - JOUR

T1 - Spectral dependencies of the quantum yield of photochemical processes on the surface of nano/micro-particulates of wide-band-gap metal oxides. IV. Theoretical modeling of the activity and selectivity of semiconductor photocatalysts with inclusion of a subsurface electric field in the space charge region

AU - Emeline, A. V.

AU - Frolov, A. V.

AU - Ryabchuk, V. K.

AU - Serpone, N.

PY - 2003/7/21

Y1 - 2003/7/21

N2 - In an earlier study (Emeline, A.V.; Ryabchuk, V.K.; Serpone, N.J. Phys. Chem. B 1999, 103, 1316) we reported the solution to the continuity equation in which we neglected electric field effects and obtained expressions for the concentrations of the charge carriers at the surface (ns), for the quantum yield (φ) of a photochemical surface redox reaction, together with an expression for the selectivity of the photocatalyst. Various considerations led us to infer and predict wavelength-dependent phenomena (quantum yields and selectivity), which were later confirmed by experimental results (Emeline, A. V.; Serpone, N. J. Phys. Chem. B 2002, 106, 12221). In this article we revisit the continuity equation but include a subsurface electric field (E) in the space charge region of the semiconductor (or dielectric) photocatalyst to assess the effect that the electric field has on the activity and selectivity of the photocatalyst. The solution to the continuity equation yields very complex expressions for ns and for φ. Nonetheless, several cases are considered which simplify the expressions. Taking E = 0, the expression for the quantum yield transforms into the identical equation obtained earlier. Some of the predictions from the expressions obtained herein also find experimental verification from considerations, for example, of the quantum yields of photoadsorption of dioxygen and dihydrogen on TiO2 particles. The agreement between the predicted spectral behavior of the ratio γ = [es]/[hs] against wavelength with the spectral dependence of φO2/φH2 is remarkable. Another no less significant conclusion from the theoretical modeling results is that a mismatch between the experimental spectral dependence of the quantum yield and the corresponding absorption band may be an indicator of the existence of a space charge region in the solid photocatalyst.

AB - In an earlier study (Emeline, A.V.; Ryabchuk, V.K.; Serpone, N.J. Phys. Chem. B 1999, 103, 1316) we reported the solution to the continuity equation in which we neglected electric field effects and obtained expressions for the concentrations of the charge carriers at the surface (ns), for the quantum yield (φ) of a photochemical surface redox reaction, together with an expression for the selectivity of the photocatalyst. Various considerations led us to infer and predict wavelength-dependent phenomena (quantum yields and selectivity), which were later confirmed by experimental results (Emeline, A. V.; Serpone, N. J. Phys. Chem. B 2002, 106, 12221). In this article we revisit the continuity equation but include a subsurface electric field (E) in the space charge region of the semiconductor (or dielectric) photocatalyst to assess the effect that the electric field has on the activity and selectivity of the photocatalyst. The solution to the continuity equation yields very complex expressions for ns and for φ. Nonetheless, several cases are considered which simplify the expressions. Taking E = 0, the expression for the quantum yield transforms into the identical equation obtained earlier. Some of the predictions from the expressions obtained herein also find experimental verification from considerations, for example, of the quantum yields of photoadsorption of dioxygen and dihydrogen on TiO2 particles. The agreement between the predicted spectral behavior of the ratio γ = [es]/[hs] against wavelength with the spectral dependence of φO2/φH2 is remarkable. Another no less significant conclusion from the theoretical modeling results is that a mismatch between the experimental spectral dependence of the quantum yield and the corresponding absorption band may be an indicator of the existence of a space charge region in the solid photocatalyst.

UR - http://www.scopus.com/inward/record.url?scp=0043206331&partnerID=8YFLogxK

M3 - Article

AN - SCOPUS:0043206331

VL - 107

SP - 7109

EP - 7119

JO - Journal of Physical Chemistry B

JF - Journal of Physical Chemistry B

SN - 1520-6106

IS - 29

ER -

ID: 35142412