Measurement of local chemical reaction rate in a microchannel by using luminol chemiluminescence

“…The reaction rate is thus proportional to the intensity of the emitted blue light. This reaction can be approximated by the bimolecular second-order reaction (Matsumoto & Matsuo, 2015),…”

“…The reaction rate is thus proportional to the intensity of the emitted blue light. This reaction can be approximated by the bimolecular second‐order reaction (Matsumoto & Matsuo, 2015), $$$\mathrm{A}+\mathrm{B}\to \mathrm{C}+\text{photon}$$$ where A and B are associated to the H 2 O 2 and the luminol species respectively. Please note that the actual reaction process is not one‐step bimolecular reaction, but it involves several reaction steps.…”

Enhanced Mixing and Reaction in Converging Flows: Theory and Pore‐Scale Imaging

“…The reaction rate is thus proportional to the intensity of the emitted blue light. This reaction can be approximated by the bimolecular second-order reaction (Matsumoto & Matsuo, 2015),…”

“…The reaction rate is thus proportional to the intensity of the emitted blue light. This reaction can be approximated by the bimolecular second‐order reaction (Matsumoto & Matsuo, 2015), $$$\mathrm{A}+\mathrm{B}\to \mathrm{C}+\text{photon}$$$ where A and B are associated to the H 2 O 2 and the luminol species respectively. Please note that the actual reaction process is not one‐step bimolecular reaction, but it involves several reaction steps.…”

Enhanced Mixing and Reaction in Converging Flows: Theory and Pore‐Scale Imaging