Advances in biophysical feedbacks and the resulting stable states in tidal flat systems

“…To address this, we have proposed a new method to control the CH 4 conversion pathway by selectively cleaving the chemical bonds in key intermediates, significantly reducing CH 3 OH peroxidation. [32,41] As illustrated in Figure 3…”

“…To address this, we have proposed a new method to control the CH 4 conversion pathway by selectively cleaving the chemical bonds in key intermediates, significantly reducing CH 3 OH peroxidation. [ 32,41 ] As illustrated in Figure , we found that the cleavage of different chemical bonds (C─O bonds or metal─O bonds) in CH 3 O* intermediates could considerably affect the peroxidation process of CH 3 OH through combined density functional theory calculations and in situ infrared spectroscopy based on 18 O isotope labeling. Specifically, timely C─O bond cleavage in CH 3 O* intermediates leads to the generated ·CH 3 rapidly combining with ·OH to form CH 3 OH.…”

Product Peroxidation Inhibition in Methane Photooxidation into Methanol

“…To address this, we have proposed a new method to control the CH 4 conversion pathway by selectively cleaving the chemical bonds in key intermediates, significantly reducing CH 3 OH peroxidation. [32,41] As illustrated in Figure 3…”

“…To address this, we have proposed a new method to control the CH 4 conversion pathway by selectively cleaving the chemical bonds in key intermediates, significantly reducing CH 3 OH peroxidation. [ 32,41 ] As illustrated in Figure , we found that the cleavage of different chemical bonds (C─O bonds or metal─O bonds) in CH 3 O* intermediates could considerably affect the peroxidation process of CH 3 OH through combined density functional theory calculations and in situ infrared spectroscopy based on 18 O isotope labeling. Specifically, timely C─O bond cleavage in CH 3 O* intermediates leads to the generated ·CH 3 rapidly combining with ·OH to form CH 3 OH.…”

Product Peroxidation Inhibition in Methane Photooxidation into Methanol