Reverse Water–Gas Shift or Sabatier Methanation on Ni(110)? Stable Surface Species at Near-Ambient Pressure

Abstract: The interaction of CO, CO2, CO + H2, CO2 + H2, and CO + CO2 + H2 with the nickel (110) single crystal termination has been investigated at 10(-1) mbar in situ as a function of the surface temperature in the 300-525 K range by means of infrared-visible sum frequency generation (IR-vis SFG) vibrational spectroscopy and by near-ambient pressure X-ray photoelectron spectroscopy (NAP-XPS). Several stable surface species have been observed and identified. Besides atomic carbon and precursors for graphenic C phases, … Show more

“…2018, 24,16097 -16103 www.chemeurj.org 2018 Wiley-VCH Verlag GmbH &Co. KGaA, Weinheim Figure 4s hows the CO 2 pressure-dependente volution of surface species in the gas mixture of CO 2 and H 2 .T he peak areaso fs urface species were normalized by the initial Cu 2p peak areas in each experiment (see the Experimental Section). [13][14][15][16] Our result offers ap romising methodt oc ontrol the formation of carbon speciest hrough tuning the CO 2 partial pressures in the reactants. At the CO 2 partial pressure of 10 À3 mbar,n oa tomico xygen was detected on the Cu(111)s urface (spectrum A, O1s).…”

“…[9,10] However, in this case, "postmortem"c haracterization does not necessarily represent the surfaceo ft he active catalyst, ast he presence of the intermediate is closely related to the partial pressure of the reactants and thep roducts. [13][14][15][16] The formation of graphitic carbon is known to be very detrimental in the reactionp rocess, because it will considerably reduce the reactivity of catalysts owing to its chemicali nertness. [8,12] As ac ommon intermediate in CO 2 conversion, graphitic carbon was widely observed in the catalytic CO 2 hydrogenation reaction.…”

Catalytic Intermediates of CO₂ Hydrogenation on Cu(111) Probed by In Operando Near‐Ambient Pressure Technique

“…2018, 24,16097 -16103 www.chemeurj.org 2018 Wiley-VCH Verlag GmbH &Co. KGaA, Weinheim Figure 4s hows the CO 2 pressure-dependente volution of surface species in the gas mixture of CO 2 and H 2 .T he peak areaso fs urface species were normalized by the initial Cu 2p peak areas in each experiment (see the Experimental Section). [13][14][15][16] Our result offers ap romising methodt oc ontrol the formation of carbon speciest hrough tuning the CO 2 partial pressures in the reactants. At the CO 2 partial pressure of 10 À3 mbar,n oa tomico xygen was detected on the Cu(111)s urface (spectrum A, O1s).…”

“…[9,10] However, in this case, "postmortem"c haracterization does not necessarily represent the surfaceo ft he active catalyst, ast he presence of the intermediate is closely related to the partial pressure of the reactants and thep roducts. [13][14][15][16] The formation of graphitic carbon is known to be very detrimental in the reactionp rocess, because it will considerably reduce the reactivity of catalysts owing to its chemicali nertness. [8,12] As ac ommon intermediate in CO 2 conversion, graphitic carbon was widely observed in the catalytic CO 2 hydrogenation reaction.…”

Catalytic Intermediates of CO₂ Hydrogenation on Cu(111) Probed by In Operando Near‐Ambient Pressure Technique

“…However, for designing a selective catalyst, it is very important to first have a fundamental understanding of the site requirements, elementary steps and intermediates, which can ultimately lead to the construction of viable mechanisms for both methanation and RWGS. Although intricate interplay between various surface species at different catalyst components that determine product selectivity has been recognized, controversies still exist regarding the detailed mechanism and the roles of surface species 10–15 . Some issues may originate from the different interrogation methods used; for example, some prior conclusions were based on kinetic and spectroscopic information acquired under transient conditions 12 .…”

Controlling selectivities in CO2 reduction through mechanistic understanding

“…From the aforementioned catalytic systems for hydrogenation and HDO, the systems based on nickel show great potential because of both low cost and high activity of Ni towards hydrogenation. Since the pioneering work by Sabatier, Ni catalysts have been widely studied and utilized as outstanding catalysts for hydrogenation. In the early days, the Ni catalyst was directly prepared by the reduction of Ni oxides .…”

The Development of Mesoporous Ni‐Based Catalysts and Evaluation of Their Catalytic and Photocatalytic Applications