Bubbles scatter light, yet that does not hurt the performance of bubbly slurry photocatalytic reactors

Abstract This paper provides a simple guideline to quantify at what gas fraction and bubble diameter bubbles start having a considerable effect on the performance of a bubbly slurry photocatalytic reactor. The local rate of photon absorption, responsible for local photoreaction rate, is affected in the presence of bubbles, as bubbles scatter the photons in all directions. Here, we consider a simple 1D description of a photoreactor, and implement a bidirectional scattering model for photocatalytic particles and bubbles to set up photon balances in the photoreactor. Both low and high light intensities are considered, with a linear and square root dependence of reaction rate on the local volumetric rate of photon absorption, respectively. The photon balances, coupled with component balances, lead to a closed-form expression for the critical gas fraction that causes a 5% deviation in the photoreaction rate, when compared to an ungassed reactor with the same amount of catalyst per unit reactor volume. We further show that in typical bubbly slurry photoreactors, with gas fractions smaller than 20% and bubble sizes of about 3 mm, the effect of bubbles on the rate of photon absorption and photoreaction is negligible. Moreover, the overall efficiencies are calculated at different gas fractions and bubble diameters. Other operational aspects of three-phase photoreactors are calculated and briefly discussed. The general conclusion is that the distribution of light inside a photoreactor is hardly affected by the presence of bubbles.

[1]  M. L. Satuf,et al.  Photocatalytic degradation of 4-chlorophenol: A kinetic study , 2008 .

[2]  J. Herrmann,et al.  HETEROGENEOUS PHOTOATALYSIS: STATE OF THE ART AND PRESENT APPLICATIONS , 2005 .

[3]  David F. Ollis,et al.  Photocatalytic degradation of organic water contaminants: Mechanisms involving hydroxyl radical attack , 1990 .

[4]  Nick Serpone,et al.  Photocatalyzed destruction of water contaminants , 1991 .

[5]  R. Grieken,et al.  Scaling-up of slurry reactors for the photocatalytic oxidation of cyanide with TiO2 and silica-supported TiO2 suspensions , 2009 .

[6]  S. Martin,et al.  Environmental Applications of Semiconductor Photocatalysis , 1995 .

[7]  J. Raulin,et al.  Heterogeneous photocatalysis: state of the art and present applications In honor of Pr. R.L. Burwell Jr. (1912–2003), Former Head of Ipatieff Laboratories, Northwestern University, Evanston (Ill). , 2005 .

[8]  J. Herrmann,et al.  Heterogeneous photocatalysis: fundamentals and applications to the removal of various types of aqueous pollutants , 1999 .

[9]  Alberto Brucato,et al.  Simplified Modeling of Radiant Fields in Heterogeneous Photoreactors. 2. Limiting “Two-Flux” Model for the Case of Reflectance Greater Than Zero , 1997 .

[10]  V. G. Pangarkar,et al.  Solar‐assisted photochemical and photocatalytic degradation of phenol , 2001 .

[11]  Kecheng Yang,et al.  Computation for angular distribution of scattered light on a coated bubble in water , 2006 .

[12]  O. Alfano,et al.  Absolute quantum yields in photocatalytic slurry reactors , 2003 .

[13]  Alberto E. Cassano,et al.  Modeling of light scattering in photochemical reactors , 1994 .

[14]  Dong Hyun Lee,et al.  Degradation of trichloroethylene by photocatalysis in an internally circulating slurry bubble column reactor. , 2005, Chemosphere.

[15]  A. Cassano,et al.  ABSORPTION AND SCATTERING COEFFICIENTS OF TITANIUM DIOXIDE PARTICULATE SUSPENSIONS IN WATER , 1996 .

[16]  V. G. Pangarkar,et al.  Photocatalytic degradation of nitrobenzene using titanium dioxide and concentrated solar radiation: chemical effects and scaleup. , 2003, Water research.

[17]  H. Lasa,et al.  Evaluation of Photon Absorption in an Aqueous TiO2 Slurry Reactor Using Monte Carlo Simulations and Macroscopic Balance. , 2010 .

[18]  Fengbao Zhang,et al.  Kinetic Study on Photocatalytic Degradation of 4BS Azo Dye Over TiO2 in Slurry , 2006 .

[19]  D. Ollis Photocatalytic purification and remediation of contaminated air and water , 2000 .

[20]  G. L. Puma,et al.  Photocatalytic oxidation of multicomponent solutions of herbicides: Reaction kinetics analysis with explicit photon absorption effects , 2006 .

[21]  A. Bard,et al.  Heterogeneous photocatalytic decomposition of benzoic acid and adipic acid on platinized titanium dioxide powder. The photo-Kolbe decarboxylative route to the breakdown of the benzene ring and to the production of butane , 1980 .

[22]  J. Moulijn,et al.  Selective photo(catalytic)-oxidation of cyclohexane: Effect of wavelength and TiO2 structure on product yields , 2006 .

[23]  D. Bahnemann,et al.  Light-induced degradation of perfluorocarboxylic acids in the presence of titanium dioxide. , 2007, Chemosphere.

[24]  A. Adesina,et al.  The photo-oxidative degradation of sodium dodecyl sulphate in aerated aqueous TiO2 suspension , 1998 .

[25]  A. Fujishima,et al.  TiO2 Photocatalysis: A Historical Overview and Future Prospects , 2005 .

[26]  M. L. Satuf,et al.  Experimental Method to Evaluate the Optical Properties of Aqueous Titanium Dioxide Suspensions , 2005 .

[27]  O. Alfano,et al.  Photocatalytic Reactions Involving Hydroxyl Radical Attack , 1997 .

[28]  O. Alfano,et al.  Scaling-up of slurry reactors for the photocatalytic degradation of 4-chlorophenol , 2007 .

[29]  Radwan Al-Rasheed,et al.  Photocatalytic degradation of humic acid in saline waters. Part 1. Artificial seawater: influence of TiO2, temperature, pH, and air-flow. , 2003, Chemosphere.

[30]  Alberto E. Cassano,et al.  Photocatalysis in water environments using artificial and solar light , 2000 .

[31]  D. Venieri,et al.  UV-A/TiO2 photocatalytic decomposition of erythromycin in water: Factors affecting mineralization and antibiotic activity , 2010 .

[32]  R. Grieken,et al.  Intrinsic kinetic modeling with explicit radiation absorption effects of the photocatalytic oxidation of cyanide with TiO2 and silica-supported TiO2 suspensions , 2008 .

[33]  Min Xia,et al.  Geometrical optics approximation of light scattered by large spheroidal bubble , 2011, Other Conferences.

[34]  S. B. Sawant,et al.  Novel solar‐based photocatalytic reactor for degradation of refractory pollutants , 2004 .

[35]  S. B. Sawant,et al.  Photocatalytic degradation of chlorobenzene using solar and artificial UV radiation , 2004 .

[36]  Alberto E. Cassano,et al.  Evaluation of Radiation Absorption in Slurry Photocatalytic Reactors. 1. Assessment of Methods in Use and New Proposal , 2000 .

[37]  S. B. Sawant,et al.  Batch and Continuous Photocatalytic Degradation of Benzenesulfonic Acid Using Concentrated Solar Radiation , 2003 .

[38]  Akira Fujishima,et al.  Titanium dioxide photocatalysis , 2000 .

[39]  J. R. Ommen,et al.  Photocatalytic-reactor efficiencies and simplified expressions to assess their relevance in kinetic experiments , 2012 .

[40]  J. Herrmann,et al.  Room temperature photocatalytic oxidation of liquid cyclohexane into cyclohexanone over neat and modified TiO2 , 1989 .

[41]  V. G. Pangarkar,et al.  Photocatalytic degradation of phenol-4-sulfonic acid using an artificial UV/TiO2 system in a slurry bubble column reactor , 2007 .