As a high-valent iron compound with Fe in the highest accessible oxidation state,ferrate(VI)brings unique opportunities for a number of areas where chemical oxidation is essential.Recently,it is emerging as a novel ox...As a high-valent iron compound with Fe in the highest accessible oxidation state,ferrate(VI)brings unique opportunities for a number of areas where chemical oxidation is essential.Recently,it is emerging as a novel oxidizing agent for materials chemistry,especially for the oxidation of carbon materials.However,the reported reactivity in liquid phase(H2SO4 medium)is confusing,which ranges from aggressive to moderate,and even incompetent.Meanwhile,the solid-state reactivity underlying the“dry”chemistry of ferrate(VI)remains poorly understood.Herein,we scrutinize the reactivity of K2FeO4 using fullerene C60 and various nanocarbons as substrates.The results unravel a modest reactivity in liquid phase that only oxidizes the active defects on carbon surface and a powerful oxidizing ability in solid state that can open the inert C=C bonds in carbon lattice.We also discuss respective benefit and limitation of the wet and dry approaches.Our work provides a rational understanding on the oxidizing ability of ferrate(VI)and can guide its application in functionalization/transformation of carbons and also other kinds of materials.展开更多
Incorporating functional molecules into molecular junc- tions as active components is a topic of major interest in the field of molecular electronics [1-7]. Many efforts have been devoted to fabricating switchable mol...Incorporating functional molecules into molecular junc- tions as active components is a topic of major interest in the field of molecular electronics [1-7]. Many efforts have been devoted to fabricating switchable molecular elec- tronic devices that are responsive to external stimuli [8,9]. Among various stimuli (e.g., redox process [ 10], pH[ 11 ], magnetic field [12]), light offers a dean, non-invasive, low-cost and easily addressable way for triggering mole- cular switches in electrical devices [13,14].展开更多
基金financial support from National Key Research and Development Program of China (2017YFA0207500)National Natural Science Foundation of China (51673114,51973111)Shanghai Science and Technology Committee (17ZR1447300)
文摘As a high-valent iron compound with Fe in the highest accessible oxidation state,ferrate(VI)brings unique opportunities for a number of areas where chemical oxidation is essential.Recently,it is emerging as a novel oxidizing agent for materials chemistry,especially for the oxidation of carbon materials.However,the reported reactivity in liquid phase(H2SO4 medium)is confusing,which ranges from aggressive to moderate,and even incompetent.Meanwhile,the solid-state reactivity underlying the“dry”chemistry of ferrate(VI)remains poorly understood.Herein,we scrutinize the reactivity of K2FeO4 using fullerene C60 and various nanocarbons as substrates.The results unravel a modest reactivity in liquid phase that only oxidizes the active defects on carbon surface and a powerful oxidizing ability in solid state that can open the inert C=C bonds in carbon lattice.We also discuss respective benefit and limitation of the wet and dry approaches.Our work provides a rational understanding on the oxidizing ability of ferrate(VI)and can guide its application in functionalization/transformation of carbons and also other kinds of materials.
基金the financial support from the National Key Research and Development Program of China (2017YFA0207500)the National Natural Science Foundation of China (51673114)Shanghai Science and Technology Committee (17ZR1447300)
文摘Incorporating functional molecules into molecular junc- tions as active components is a topic of major interest in the field of molecular electronics [1-7]. Many efforts have been devoted to fabricating switchable molecular elec- tronic devices that are responsive to external stimuli [8,9]. Among various stimuli (e.g., redox process [ 10], pH[ 11 ], magnetic field [12]), light offers a dean, non-invasive, low-cost and easily addressable way for triggering mole- cular switches in electrical devices [13,14].
