Cooperative carbon capture and steam regeneration with tetraamine-appended metal–organic frameworks

Eugene J. Kim; Rebecca L. Siegelman; Henry Z. H. Jiang; Alexander C. Forse; Jung‐Hoon Lee; Jeffrey D. Martell; Phillip J. Milner; J.M. Falkowski; Jeffrey B. Neaton; Jeffrey A. Reimer; Simon C. Weston; Jeffrey R. Long

doi:10.1126/science.abb3976

Cooperative carbon capture and steam regeneration with tetraamine-appended metal–organic frameworks

Eugene J. Kim(University of California, Berkeley), Rebecca L. Siegelman(Lawrence Berkeley National Laboratory), Henry Z. H. Jiang(University of California, Berkeley), Alexander C. Forse(Energy Biosciences Institute), Jung‐Hoon Lee(Lawrence Berkeley National Laboratory), Jeffrey D. Martell(University of California, Berkeley), Phillip J. Milner(University of California, Berkeley), J.M. Falkowski(ExxonMobil (United States)), Jeffrey B. Neaton(Lawrence Berkeley National Laboratory), Jeffrey A. Reimer(Lawrence Berkeley National Laboratory), Simon C. Weston(ExxonMobil (United States)), Jeffrey R. Long(Lawrence Berkeley National Laboratory)

Science

July 24, 2020

10.1126/science.abb3976

Cited by 428Open Access

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Abstract

Steaming out captured CO 2 Although natural gas is less carbon dioxide (CO 2 )–intensive than coal, capturing its emitted CO 2 can be more challenging because combined-cycle natural gas combustion has a CO 2 concentration that is only one-third of that of coal combustion and contains high concentrations of oxygen and water. Kim et al. report on a tetraamine-functionalized magnesium metal–organic framework that displays two-step cooperative CO 2 adsorption that leads to a high CO 2 capacity and adsorption enthalpy (see the Perspective by Peh and Zhao). This material could capture CO 2 from humid air and could be regenerated with steam, a method that is more economical than temperature or pressure swing methods. Science , this issue p. 392 ; see also p. 372

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