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Enhancement of Electrochemical Nitrogen Reduction Activity and Suppression of Hydrogen Evolution Reaction for Transition Metal Oxide Catalysts: The Role of Proton Intercalation and Heteroatom Doping

Qingdong Li, Oguz Kaan Kucukosman, Qingquan Ma, Junjie Ouyang, Pavel Kucheryavy, Hengfei Gu, Conor Long, Z. Y. Zhang, Joshua Young, Jenny V. Lockard, Eric Garfunkel, Jianan Gao, Wen Zhang, Huixin He

2024ACS Catalysis23 citationsDOI

Abstract

During the electrochemical nitrogen reduction reaction (eNRR) and hydrogen evolution reaction (HER), interstitial proton intercalation readily occurs in some transition metal oxide (TMO) catalysts and changes their d-band electronic structure. This work fabricated phosphorus (P)-doped tungsten oxide (WO 3 ) with enriched oxygen vacancies (OVs) to study the impact of proton intercalation and heteroatom doping on eNRR and HER. Our results demonstrated that the electronic structure of the P-OV-WO 3 catalyst was altered by in situ proton intercalation as indicated by the greater negative onset potential of eNRR at −0.05 V compared to the proton intercalation potential of 0.3 V versus reversible hydrogen electrode (RHE). Compared to the non-P-doped WO 3, the introduction of P doping in WO 3 (e.g., 4.8 at. %) led to a reduction of more than 36% in proton intercalation. As a result, the HER activity of the P-OV-WO 3 was significantly suppressed, as demonstrated by a considerably negative shift of the onset HER potential from −0.06 to −0.15 V and a slower HER kinetics with the Tafel slope increased from 129.0 to 343.1 mV/dec. Density functional theory calculations revealed the synergy of the proton intercalation, substitutional P doping, and the associated OVs in the improvement of N 2 activation and hydrogenation in eNRR. The increased eNRR and the suppressed HER led to a high Faradaic efficiency (FE) of 64.1% and the NH 3 yield of 24.5 μg·mg cat –1 h –1 at −0.15 V versus RHE in H 2 SO 4 (pH = 2) as the electrolyte. The specific NH 3 yield is more than 20 times higher than that of C-WO 3 (1.1 μg·mg cat –1 h –1 with a FE of 20%). The results exceed most of the reported eNRR performances for TMO-based catalysts. Thus, the synergistic proton intercalation and P doping could lead to newer designs and applications of TMO-based catalysts for improved eNRR while suppressing the competing HER.

Topics & Concepts

Intercalation (chemistry)CatalysisTafel equationHeteroatomInorganic chemistryElectrochemistryChemistryOxideReversible hydrogen electrodeHydrogenFaraday efficiencyTransition metalMaterials scienceElectrodePhysical chemistryWorking electrodeRing (chemistry)Organic chemistryBiochemistryAmmonia Synthesis and Nitrogen ReductionElectrocatalysts for Energy ConversionAdvanced Photocatalysis Techniques