Determination of the photocatalytic deposition velocity

A. Engel; A. Glyk; A. Hülsewig; J. Große; R. Dillert; D.W. Bahnemann

doi:10.1016/j.cej.2014.03.040

Details

Original language	English
Pages (from-to)	88-94
Number of pages	7
Journal	Chemical engineering journal
Volume	261
Publication status	Published - 1 Feb 2015

Abstract

Microscale atmospheric dispersion models have been employed recently to predict the possible effect of photocatalytically active surfaces on the air pollution in urban areas. These simulations use the photocatalytic deposition velocity as an input value. However, no generally accepted experimental method for the determination of the photocatalytic deposition velocity is available. Here a method to determine the photocatalytic deposition velocity is proposed which is based on ISO 22179-1 et seqq. specifying test methods for the determination of the air-purification performance of materials that contain a photocatalyst or have photocatalytic films on the surface. It is assumed that the rate of the photocatalytic surface reaction of a species i, ^AR _i, is given by an expression having the mathematical form ^AR _i= ^Ak _iK _ic _i/(1+K _ic _i) where the kinetic parameters ^Ak _i and K _i are variables depending on the photon flux, the temperature, the humidity and the concentration of other pollutants. Under steady state conditions the mole balance of a differential volume of a fluid element inside the plug flow reactor described in the cited ISO standards reads Y= ^Ak _iK _iX-const(i). This equation is a linear equation of the two variables Y=ln(c _in, _i/c _out, _i)/(c _in, _i-c _out, _i) and X=A _r/(q _V(c _in, _i-c _out, _i)) where c _in, _i, c _out, _i, A _r, and q _V are the inlet and outlet concentration of the pollutant i under consideration, the irradiated photocatalytically active surface, and the volumetric flow rate through the photocatalytic reactor, respectively. It is argued that the slope ^Ak _iK _i of this equation is the demanded photocatalytic deposition velocity ν _pc, _i. Thus, the measurement of c _out, _i at varying c _in, _i makes the photocatalytic deposition velocity accessible.

Keywords

Air purification, Deposition velocity, Heterogeneous photocatalysis, Nitrogen oxide, Titanium dioxide

ASJC Scopus subject areas

Chemistry(all)
General Chemistry
Environmental Science(all)
Environmental Chemistry
Chemical Engineering(all)
General Chemical Engineering
Engineering(all)
Industrial and Manufacturing Engineering

Sustainable Development Goals

SDG 11 - Sustainable Cities and Communities

Cite this

Determination of the photocatalytic deposition velocity. / Engel, A.; Glyk, A.; Hülsewig, A. et al.
In: Chemical engineering journal, Vol. 261, 01.02.2015, p. 88-94.

Research output: Contribution to journal › Article › Research › peer review

Engel, A, Glyk, A, Hülsewig, A, Große, J, Dillert, R & Bahnemann, DW 2015, 'Determination of the photocatalytic deposition velocity', Chemical engineering journal, vol. 261, pp. 88-94. https://doi.org/10.1016/j.cej.2014.03.040

Engel, A., Glyk, A., Hülsewig, A., Große, J., Dillert, R., & Bahnemann, D. W. (2015). Determination of the photocatalytic deposition velocity. Chemical engineering journal, 261, 88-94. https://doi.org/10.1016/j.cej.2014.03.040

Engel A, Glyk A, Hülsewig A, Große J, Dillert R, Bahnemann DW. Determination of the photocatalytic deposition velocity. Chemical engineering journal. 2015 Feb 1;261:88-94. doi: 10.1016/j.cej.2014.03.040

Engel, A. ; Glyk, A. ; Hülsewig, A. et al. / Determination of the photocatalytic deposition velocity. In: Chemical engineering journal. 2015 ; Vol. 261. pp. 88-94.

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title = "Determination of the photocatalytic deposition velocity",

abstract = "Microscale atmospheric dispersion models have been employed recently to predict the possible effect of photocatalytically active surfaces on the air pollution in urban areas. These simulations use the photocatalytic deposition velocity as an input value. However, no generally accepted experimental method for the determination of the photocatalytic deposition velocity is available. Here a method to determine the photocatalytic deposition velocity is proposed which is based on ISO 22179-1 et seqq. specifying test methods for the determination of the air-purification performance of materials that contain a photocatalyst or have photocatalytic films on the surface. It is assumed that the rate of the photocatalytic surface reaction of a species i, AR i, is given by an expression having the mathematical form AR i= Ak iK ic i/(1+K ic i) where the kinetic parameters Ak i and K i are variables depending on the photon flux, the temperature, the humidity and the concentration of other pollutants. Under steady state conditions the mole balance of a differential volume of a fluid element inside the plug flow reactor described in the cited ISO standards reads Y= Ak iK iX-const(i). This equation is a linear equation of the two variables Y=ln(c in, i/c out, i)/(c in, i-c out, i) and X=A r/(q V(c in, i-c out, i)) where c in, i, c out, i, A r, and q V are the inlet and outlet concentration of the pollutant i under consideration, the irradiated photocatalytically active surface, and the volumetric flow rate through the photocatalytic reactor, respectively. It is argued that the slope Ak iK i of this equation is the demanded photocatalytic deposition velocity ν pc, i. Thus, the measurement of c out, i at varying c in, i makes the photocatalytic deposition velocity accessible. ",

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author = "A. Engel and A. Glyk and A. H{\"u}lsewig and J. Gro{\ss}e and R. Dillert and D.W. Bahnemann",

note = "Funding information: This work which was funded in part by the German Federal Ministry of Education and Research (contract no. 03X0069F, HelioClean – Nanotechnologisch funktionalisierte Baustoffe zur solarkatalytischen Luft- und Oberfl{\"a}chenreinigung“) was presented in part by R.D. at the 2nd International Conference on Photocatalytic and Advanced Oxidation Technologies for Treatment of Water, Air, Soil and Surfaces (PAOT-2), September 9–12, 2013, Gdansk, Poland, and the 3rd European Symposium on Photocatalysis (JEP 2013), September 25–27, 2013, Portoro{\v z}, Slovenia. The authors thank Dr. Gerald Burgeth, Sto AG, for the cession of the paint samples. R.D. thanks the Leibniz University Hannover and Prof. Dr. D. Bahnemann for granting him a leave of absence.",

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AU - Engel, A.

AU - Glyk, A.

AU - Hülsewig, A.

AU - Große, J.

AU - Dillert, R.

AU - Bahnemann, D.W.

N1 - Funding information: This work which was funded in part by the German Federal Ministry of Education and Research (contract no. 03X0069F, HelioClean – Nanotechnologisch funktionalisierte Baustoffe zur solarkatalytischen Luft- und Oberflächenreinigung“) was presented in part by R.D. at the 2nd International Conference on Photocatalytic and Advanced Oxidation Technologies for Treatment of Water, Air, Soil and Surfaces (PAOT-2), September 9–12, 2013, Gdansk, Poland, and the 3rd European Symposium on Photocatalysis (JEP 2013), September 25–27, 2013, Portorož, Slovenia. The authors thank Dr. Gerald Burgeth, Sto AG, for the cession of the paint samples. R.D. thanks the Leibniz University Hannover and Prof. Dr. D. Bahnemann for granting him a leave of absence.

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N2 - Microscale atmospheric dispersion models have been employed recently to predict the possible effect of photocatalytically active surfaces on the air pollution in urban areas. These simulations use the photocatalytic deposition velocity as an input value. However, no generally accepted experimental method for the determination of the photocatalytic deposition velocity is available. Here a method to determine the photocatalytic deposition velocity is proposed which is based on ISO 22179-1 et seqq. specifying test methods for the determination of the air-purification performance of materials that contain a photocatalyst or have photocatalytic films on the surface. It is assumed that the rate of the photocatalytic surface reaction of a species i, AR i, is given by an expression having the mathematical form AR i= Ak iK ic i/(1+K ic i) where the kinetic parameters Ak i and K i are variables depending on the photon flux, the temperature, the humidity and the concentration of other pollutants. Under steady state conditions the mole balance of a differential volume of a fluid element inside the plug flow reactor described in the cited ISO standards reads Y= Ak iK iX-const(i). This equation is a linear equation of the two variables Y=ln(c in, i/c out, i)/(c in, i-c out, i) and X=A r/(q V(c in, i-c out, i)) where c in, i, c out, i, A r, and q V are the inlet and outlet concentration of the pollutant i under consideration, the irradiated photocatalytically active surface, and the volumetric flow rate through the photocatalytic reactor, respectively. It is argued that the slope Ak iK i of this equation is the demanded photocatalytic deposition velocity ν pc, i. Thus, the measurement of c out, i at varying c in, i makes the photocatalytic deposition velocity accessible.

AB - Microscale atmospheric dispersion models have been employed recently to predict the possible effect of photocatalytically active surfaces on the air pollution in urban areas. These simulations use the photocatalytic deposition velocity as an input value. However, no generally accepted experimental method for the determination of the photocatalytic deposition velocity is available. Here a method to determine the photocatalytic deposition velocity is proposed which is based on ISO 22179-1 et seqq. specifying test methods for the determination of the air-purification performance of materials that contain a photocatalyst or have photocatalytic films on the surface. It is assumed that the rate of the photocatalytic surface reaction of a species i, AR i, is given by an expression having the mathematical form AR i= Ak iK ic i/(1+K ic i) where the kinetic parameters Ak i and K i are variables depending on the photon flux, the temperature, the humidity and the concentration of other pollutants. Under steady state conditions the mole balance of a differential volume of a fluid element inside the plug flow reactor described in the cited ISO standards reads Y= Ak iK iX-const(i). This equation is a linear equation of the two variables Y=ln(c in, i/c out, i)/(c in, i-c out, i) and X=A r/(q V(c in, i-c out, i)) where c in, i, c out, i, A r, and q V are the inlet and outlet concentration of the pollutant i under consideration, the irradiated photocatalytically active surface, and the volumetric flow rate through the photocatalytic reactor, respectively. It is argued that the slope Ak iK i of this equation is the demanded photocatalytic deposition velocity ν pc, i. Thus, the measurement of c out, i at varying c in, i makes the photocatalytic deposition velocity accessible.

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Research@Leibniz University