392059 Aqueous Phase Hydrogenation of Amine Captured CO2

Tuesday, November 18, 2014: 8:50 AM
308 (Hilton Atlanta)
Mi Lu1, Ji Su1 and Hongfei Lin2, (1)Chemical & Materials Engineering, University of Nevada, Reno, NV, (2)Chemical and Materials Engineering, University of Nevada, Reno, Reno, NV

Carbon dioxide (CO2) will become increasingly available as a cheap, renewable, and abundant carbon feedstock as commercialization for the carbon capture and storage (CCS) from power plants is coming into play. Development of highly efficient methods for CO2 reduction would greatly increase the range of possible products derivable from CO2. The hydrogenation of CO2 to formic acid appears to be a straightforward approach to utilize CO2. This reaction in the gas phase is endergonic (DGo298 = +33 kJ mol-1), i.e. thermodynamically unfavourable. However, the same reaction in the aqueous phase is exergonic (DGo298 = -4 kJ mol-1).   Moreover, bases in aqueous solutions, e.g. NH3, enhance the hydrogenation of CO2 (DGo298 = -10 kJ mol-1). Hydrogenation of amine-CO2 adducts or ammonium carbonates in aqueous solutions are thus thermodynamically favorable to produce formic acid. However, there are only few studies of hydrogenation of CO2 to formic acid in the presence of amines with homogeneous catalytic systems. And the homogeneous catalysts were not stable or their performance was suppressed when water was present.  Herein, we develop the carbon capture and conversion (CCC) process to convert amine-CO2 adducts to formic acid with supported metal nano-cluster catalysts in aqueous media. To design the stable heterogeneous catalytic system for this reaction, we aim to directly convert the amine-CO2 adducts from the CO2 capture step of CCS process to formic acid, saving the energy and cost for separating, compressing, and transporting CO2 in the storage step of a CCS process. The effects of the amine structures and the aqueous phase intermediates on the yield of formic acid were also investigated.

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See more of this Session: Catalyst Design for Environmental Applications
See more of this Group/Topical: Catalysis and Reaction Engineering Division