Experimental study of a bimolecular reaction in Poiseuille Flow

A bimolecular chemical reaction (reactantl + reactant2 → products) in laminar Poiseuille flow is experimentally observed using a spectrophotometer. The reaction rate (rm) follows the second‐order rate law; that is, rm = кC1C2, where cm(m=1, 2) are the reactant concentrations. The reaction rate const...

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Veröffentlicht in:	Water resources research 1998-08, Vol.34 (8), p.1997-2004
Hauptverfasser:	Kapoor, Vivek, Jafvert, Chad T., Lyn, Dennis A.
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Sprache:	eng
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container_end_page	2004
container_issue	8
container_start_page	1997
container_title	Water resources research
container_volume	34
creator	Kapoor, Vivek Jafvert, Chad T. Lyn, Dennis A.
description	A bimolecular chemical reaction (reactantl + reactant2 → products) in laminar Poiseuille flow is experimentally observed using a spectrophotometer. The reaction rate (rm) follows the second‐order rate law; that is, rm = кC1C2, where cm(m=1, 2) are the reactant concentrations. The reaction rate constant к is independently estimated by monitoring the reaction kinetics in a completely mixed batch reactor using the stopped‐flow technique. In the reactive transport experiments, the reactants are introduced in a tube and are initially separated by a sharp interface. The variation of the fluid velocity over the cross section of the tube causes the concentrations of the reactants to vary around their cross‐sectional average values (c¯m). These spatial variations in the concentrations (c′m) influence the overall reaction rate. The cross‐sectional average reaction rate is given by , where is the segregation intensity. The experimentally observed breakthrough concentration of the product is in agreement with a numerical model that accounts for the effects of the segregation intensity. On ignoring the influence of the segregation intensity, the predicted product concentration substantially exceeds the experimental observations. This shows that for initially non‐overlapping reactants the segregation intensity is negative (s < 0) and that the overall chemical transformation rate in flowing systems can be significantly different from that implied by substituting the mean concentrations in the expression for the reaction rate.
doi_str_mv	10.1029/98WR01649
format	Article
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The reaction rate (rm) follows the second‐order rate law; that is, rm = кC1C2, where cm(m=1, 2) are the reactant concentrations. The reaction rate constant к is independently estimated by monitoring the reaction kinetics in a completely mixed batch reactor using the stopped‐flow technique. In the reactive transport experiments, the reactants are introduced in a tube and are initially separated by a sharp interface. The variation of the fluid velocity over the cross section of the tube causes the concentrations of the reactants to vary around their cross‐sectional average values (c¯m). These spatial variations in the concentrations (c′m) influence the overall reaction rate. The cross‐sectional average reaction rate is given by , where is the segregation intensity. The experimentally observed breakthrough concentration of the product is in agreement with a numerical model that accounts for the effects of the segregation intensity. On ignoring the influence of the segregation intensity, the predicted product concentration substantially exceeds the experimental observations. 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The experimentally observed breakthrough concentration of the product is in agreement with a numerical model that accounts for the effects of the segregation intensity. On ignoring the influence of the segregation intensity, the predicted product concentration substantially exceeds the experimental observations. 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title	Experimental study of a bimolecular reaction in Poiseuille Flow
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