(646d) Rates and Reversibility for CO2 Hydrogenation on Cu-Based Catalysts | AIChE

(646d) Rates and Reversibility for CO2 Hydrogenation on Cu-Based Catalysts

Authors 

Lin, T. - Presenter, University of Minnesota
Bhan, A., University of Minnesota
Methanol synthesis via CO2 hydrogenation, unlike CO hydrogenation, occurs concurrently with reverse water-gas shift (RWGS), thereby reducing methanol selectivity. We report that CO2 hydrogenation rates and selectivity are single-valued functions of hydrogen pressure; while CO2 partial pressure does not impact methanol selectivity during CO2 hydrogenation on Cu/ZnO/Al2O3, increasing H2 partial pressure enhances methanol selectivity as methanol synthesis exhibits an apparent first order dependence on PH2 while RWGS is zeroth order in PH2. These apparent reaction orders persist from CO2:H2 = 1:1 to 1:120 such that changes in PH2 can increase methanol selectivity from 5 to 80%. Rate measurements on Cu/Al2O3 catalysts in combination with in situ chemical titrations using methylene chloride demonstrate that site density is invariant with H2 partial pressure; the apparent first order dependence on PH2 for methanol synthesis indicates a dearth of H* species at all process conditions during CO2 hydrogenation on Cu/ZnO/Al2O3.

Partial pressures of products were varied both by purposeful addition of product species to the CO2/H2 feedstock and by operation of reaction under reversible regimes. These results consistently demonstrate H­2O preferentially inhibits the unidirectional forward rate of methanol synthesis while CO inhibits methanol synthesis and RWGS equally such that methanol selectivity is unchanged. These differences in H2O and H2 dependencies suggest distinct pathways and intermediates for methanol synthesis and RWGS. Altogether, our work provides novel kinetic and mechanistic insights regarding rates and reversibility of elementary steps involved in CO2 hydrogenation on Cu/ZnO/Al2O3 catalysts.