The efficient separation of butadiene(1,3-C_(4)H_(6))from C_(4)hydrocarbons is a critical step in petrochemical processes.However,the traditional cryogenic distillation suffers from energy-intensity and serious enviro...The efficient separation of butadiene(1,3-C_(4)H_(6))from C_(4)hydrocarbons is a critical step in petrochemical processes.However,the traditional cryogenic distillation suffers from energy-intensity and serious environmental stress,necessitating the development of alternative technologies for efficient 1,3-C_(4)H_(6)separation.Herein,a 1,3-C_(4)H_(6)recognition mixed matrix membrane is reported via incorporating metal copper encapsulated a metal-organic framework(CuBTC@Cu)into elastic poly(dimethylsiloxane)(PDMS).The resulting CuBTC@Cu/PDMS membrane can efficient separate 1,3-C_(4)H_(6)from various C_(4)hydrocarbons including 1,3-C_(4)H_(6)/n-C_(4)H_(8),1,3-C_(4)H_(6)/iso-C_(4)H_(8),1,3-C_(4)H_(6)/n-C_(4)H_(10)and 1,3-C_(4)H_(6)/iso-C_(4)H_(10),yielding superior selectivity of 5.11,6.35,4.78,and 10.30,respectively,with 1,3-C_(4)H_(6)permeability of 53240 Barrer.Notably,the appropriateπ-complexation interaction between butadiene molecules and CuBTC@Cu as well as suitable transmission channel size enable the membrane only permeable to 1,3-C_(4)H_(6)and block the permeation of other C_(4)hydrocarbons,showing a unique 1,3-C_(4)H_(6)recognition behavior in membrane separation.The concept of affinity-relying separation combining molecular sieving would open a new direction for designing gas membranes for efficient light hydrocarbon separations.展开更多
Natural gas and biogas are important resources.The enrichment of CH4 is necessary for increasing the caloric value of feed gas[1-3].Membrane-based gas separation technology is more energyefficient with continuous oper...Natural gas and biogas are important resources.The enrichment of CH4 is necessary for increasing the caloric value of feed gas[1-3].Membrane-based gas separation technology is more energyefficient with continuous operation and more environmentally friendly than conventional gas separation technologies,and it has strong application prospects in the field of industrial separation[1,4].Metal-organic frameworks(MOFs)have high porosity,adjustable aperture,highly diversified structures and satisfactory chemical stability,which inspire many researchers to explore their applications in membrane fabrication for gas separation[2,3,5].Pure MOF membranes that are fabricated on porous substrates can realize high gas permeance and satisfactory selectivity simultaneously and have been attracted substantial attention[6,7].展开更多
基金the National Key R&D Program of China(grant number:2021YFB3802200)the Natural Science Foundation of China(grant number:22038010).
文摘The efficient separation of butadiene(1,3-C_(4)H_(6))from C_(4)hydrocarbons is a critical step in petrochemical processes.However,the traditional cryogenic distillation suffers from energy-intensity and serious environmental stress,necessitating the development of alternative technologies for efficient 1,3-C_(4)H_(6)separation.Herein,a 1,3-C_(4)H_(6)recognition mixed matrix membrane is reported via incorporating metal copper encapsulated a metal-organic framework(CuBTC@Cu)into elastic poly(dimethylsiloxane)(PDMS).The resulting CuBTC@Cu/PDMS membrane can efficient separate 1,3-C_(4)H_(6)from various C_(4)hydrocarbons including 1,3-C_(4)H_(6)/n-C_(4)H_(8),1,3-C_(4)H_(6)/iso-C_(4)H_(8),1,3-C_(4)H_(6)/n-C_(4)H_(10)and 1,3-C_(4)H_(6)/iso-C_(4)H_(10),yielding superior selectivity of 5.11,6.35,4.78,and 10.30,respectively,with 1,3-C_(4)H_(6)permeability of 53240 Barrer.Notably,the appropriateπ-complexation interaction between butadiene molecules and CuBTC@Cu as well as suitable transmission channel size enable the membrane only permeable to 1,3-C_(4)H_(6)and block the permeation of other C_(4)hydrocarbons,showing a unique 1,3-C_(4)H_(6)recognition behavior in membrane separation.The concept of affinity-relying separation combining molecular sieving would open a new direction for designing gas membranes for efficient light hydrocarbon separations.
基金supported by the National Natural Science Foundation of China(21536001,21878229,and 21908163)the Science and Technology Plans of Tianjin(18PTSYJC00180 and 19PTSYJC00020)。
文摘Natural gas and biogas are important resources.The enrichment of CH4 is necessary for increasing the caloric value of feed gas[1-3].Membrane-based gas separation technology is more energyefficient with continuous operation and more environmentally friendly than conventional gas separation technologies,and it has strong application prospects in the field of industrial separation[1,4].Metal-organic frameworks(MOFs)have high porosity,adjustable aperture,highly diversified structures and satisfactory chemical stability,which inspire many researchers to explore their applications in membrane fabrication for gas separation[2,3,5].Pure MOF membranes that are fabricated on porous substrates can realize high gas permeance and satisfactory selectivity simultaneously and have been attracted substantial attention[6,7].
