Litcius/Paper detail

DFT + <i>U</i> Study of Strain-Engineered CO<sub>2</sub> Reduction on a CeO<sub>2–<i>x</i></sub> (111) Facet

Jens Vive Kildgaard, Heine Anton Hansen, Tejs Vegge

2021The Journal of Physical Chemistry C33 citationsDOIOpen Access PDF

Abstract

Ceria is a promising material for cathodes in high-temperature CO2 electrolysis cells because ceria can become a mixed electronic and ionic conductor through doping, which enables a high surface area for electrocatalysis. Here, we systemically investigate the effect of strain to enhance the activity for electrocatalytic CO2RR on CeO2(111) using density functional theory corrected for on-site Coulomb interactions (DFT + U). We find that tensile strain decreases the oxygen vacancy formation energy due to a downshift of the Ce 4f orbital energy, in agreement with the larger size of the Ce3+ ion than the Ce4+ ion. The corresponding upshift in the Ce f-band center with compressive strain destabilizes the formation energy of the critical surface oxygen vacancies and reduces the energetic span of the reduction reaction, leading to a 4 orders of magnitude higher turnover frequency at 800 K for 4% compressive strain. These findings shed new light on possible pathways to enhance the catalytic activity for CO2RR on CeO2(111) and related catalytic systems by strain engineering.

Topics & Concepts

Density functional theoryMaterials scienceElectrocatalystStrain (injury)Ionic bondingVacancy defectCathodeCatalysisIonCrystallographyPhysical chemistryChemistryElectrochemistryElectrodeComputational chemistryBiochemistryInternal medicineMedicineOrganic chemistryCatalytic Processes in Materials ScienceCO2 Reduction Techniques and CatalystsAdvancements in Solid Oxide Fuel Cells