Abstract
Despite its high thermodynamic stability, the presence of a negative electric field is known to facilitate the activation of CO2 through electrostatic effects. To utilize electric fields for a reverse water gas shift reaction, it is critical to elucidate the role of an electric field on a catalyst surface toward activating a CO2 molecule. We conduct a first-principles study to gain an atomic and electronic description of adsorbed CO2 on YSZ (111) surfaces when external electric fields of +1 V/Å, 0 V/Å, and −1 V/Å are applied. We find that the application of an external electric field generally destabilizes oxide bonds, where the direction of the field affects the location of the most favorable oxygen vacancy. The direction of the field also drastically impacts how CO2 adsorbs on the surface. CO2 is bound by physisorption when a +1 V/Å field is applied, a similar interaction as to how it is adsorbed in the absence of a field. This interaction changes to chemisorption when the surface is exposed to a −1 V/Å field value, resulting in the formation of a CO3− complex. The strong interaction is reflected through a direct charge transfer and an orbital splitting within the Olatticep-states. While CO2 remains physisorbed when a +1 V/Å field value is applied, our total density of states analysis indicates that a positive field pulls the charge away from the adsorbate, resulting in a shift of its bonding and antibonding peaks to higher energies, allowing a stronger interaction with YSZ (111). Ultimately, the effect of an electric field toward CO2 adsorption is not negligible, and there is potential in utilizing electric fields to favor the thermodynamics of CO2 reduction on heterogeneous catalysts.
Highlights
Introduction iationsGlobal energy demand has rapidly increased over the past decades due to the increase in world population and rapid economic development of developing countries [1,2]
YSZ (111), we investigated electronic structure analysis through a partial densityofofstates states (PDOS)
To harness electric fields for enhancing CO2 reduction, we first need an understanding of its effects toward CO2 activation
Summary
Global energy demand has rapidly increased over the past decades due to the increase in world population and rapid economic development of developing countries [1,2]. It is expected that this increasing trend in the world energy demand will continue in the foreseeable future. In order to meet this energy demand, the consumption of fossil fuels has dramatically increased and is predicted to continuously increase as well [3]. Because fossil fuels produce large quantities of CO2 when burned, their large consumption has negatively impacted our environments (e.g., global warming due to CO2 accumulation in the atmosphere) [4,5]. Among various alternative and renewable energy technologies, hydrogen-based technologies are considered as one of the most promising strategies to replace conventional fossil fuel-based energy technologies because it only produces.
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