With the strict control of sulfur content in fuels,oxidative desulfurization(ODS),a promising desulphurization technology,needs to be continuously developed.In this study,we integrated multiple approaches(fabricating ...With the strict control of sulfur content in fuels,oxidative desulfurization(ODS),a promising desulphurization technology,needs to be continuously developed.In this study,we integrated multiple approaches(fabricating a porous structure,increasing phosphomolybdic acid(PMo)loading,improving amphiphilicity,and enhancing the intrinsic activity of PMo using a reductive framework)into PAF-54 carriers to improve ODS catalytic ability.The catalytic performance suggested that PAF-54 was not simply used as a carrier for PMo by physical integration.During the binding process,electron transfer between PAF-54 and PMo formed Mo^(5+)with superior catalytic activity.Owing to the presence of PAF-54,the catalytic activity of PMo as the active component qualitatively improved to achieve rapid and efficient desulfurization.More importantly,we found that other nitrogen-rich porous organic polymers can also reduce some of Mo^(6+)in PMo during loading,and its formation mechanism was investigated.This work provides a feasible strategy for designing highly efficient DOS catalysts.展开更多
基金supported by Hainan Provincial Natural Science Foundation of China(220MS005)the National Key R&D Program of China(2022YFB3805902)+3 种基金the National Natural Science Foundation of China(22361017 and 22075040)the Innovation Platform for Academicians of Hainan Provincethe Specific Research Fund of the Innovation Platform for Academicians of Hainan Province(YSPTZX202321)the International Science&Technology Cooperation Program of Hainan Province(GHYF2022006)。
文摘With the strict control of sulfur content in fuels,oxidative desulfurization(ODS),a promising desulphurization technology,needs to be continuously developed.In this study,we integrated multiple approaches(fabricating a porous structure,increasing phosphomolybdic acid(PMo)loading,improving amphiphilicity,and enhancing the intrinsic activity of PMo using a reductive framework)into PAF-54 carriers to improve ODS catalytic ability.The catalytic performance suggested that PAF-54 was not simply used as a carrier for PMo by physical integration.During the binding process,electron transfer between PAF-54 and PMo formed Mo^(5+)with superior catalytic activity.Owing to the presence of PAF-54,the catalytic activity of PMo as the active component qualitatively improved to achieve rapid and efficient desulfurization.More importantly,we found that other nitrogen-rich porous organic polymers can also reduce some of Mo^(6+)in PMo during loading,and its formation mechanism was investigated.This work provides a feasible strategy for designing highly efficient DOS catalysts.
