期刊
JOURNAL OF PHYSICAL CHEMISTRY B
卷 126, 期 48, 页码 10136-10145出版社
AMER CHEMICAL SOC
DOI: 10.1021/acs.jpcb.2c04682
关键词
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The transfer of oxygen at the air-water interface plays a crucial role in the spatiotemporal behavior of the iodine clock reaction with sulfite. The reaction of oxygen with sulfite controls the switch between low-iodine and high-iodine states under well-stirred conditions and drives the formation of transient iodine gradients. In thin layers, the reaction couples with convective instability at the air-water interface, forming an extended network-like structure of iodine that develops into a spotted pattern at the base of the layer.
There is increasing interest in using chemical clock reactions to drive material formation; however, these reactions are often subject to chemoconvective effects, and control of such systems remains challenging. Here, we show how the transfer of oxygen at the air-water interface plays a crucial role in the spatiotemporal behavior of the iodine clock reaction with sulfite. A kinetic model was developed to demonstrate how the reaction of oxygen with sulfite can control a switch from a low-iodine to high-iodine state under well-stirred conditions and drive the formation of transient iodine gradients in unstirred solutions. In experiments in thin layers with optimal depths, the reaction couples with convective instability at the air-water interface forming an extended network-like structure of iodine at the surface that develops into a spotted pattern at the base of the layer. Thus, oxygen drives the spatial separation of iodine states essential for patterns in this system and may influence pattern selection in other clock reaction systems with sulfite.
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