2019
DOI: 10.1002/aenm.201903137
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Atomically Dispersed Mo Supported on Metallic Co9S8 Nanoflakes as an Advanced Noble‐Metal‐Free Bifunctional Water Splitting Catalyst Working in Universal pH Conditions

Abstract: sunlight for sustainable energy conversion and storage. [1] For renewable and efficient hydrogen production, electrochemical water splitting employing renewable electrical energy is a promising route due to its inherent advantages, including readily available reactant, stable output, and feasibility of large-scale production. [2] However, the large overpotential (η) of both hydrogen evolution reaction (HER) and oxygen evolution reaction (OER) greatly limited their practical applications. Moreover, due to the… Show more

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Cited by 191 publications
(114 citation statements)
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“…As displayed in Figure a, a low cell voltage of only 1.46 V was required for the electrolyzer to deliver a current density of 10 mA cm –2 which is superior to Pt/C/FF||RuO 2 /FF with 1.52 V (Figure S15, Supporting Information). The electrolyzer composed of FFNaRu and FFNaNi presented electrocatalytic performances comparable to previous materials, such as a‐RuTe 2 PNR, [ 11d ] NiFeRu‐LDH, [ 20 ] Mo‐Co 9 S 8 @C, [ 21 ] Pt‐CoS 2 /CC, [ 22 ] CoFeZr oxides/NF, [ 2a ] Ir/MoS 2 /CF, [ 23 ] Ru NP/C+NiFe LDH, [ 24 ] RuCu NSs/C, [ 25 ] and CoFe‐CDs+CoFeRu@C [ 26 ] (Figure 6b) and other reported nanomaterials (Table S3, Supporting Information). Moreover, the long‐term stability at a current density of 10 mA cm –2 showed negligible current loss after 12 h, demonstrating its superior overall water‐splitting durability (Figure 6c).…”
Section: Resultsmentioning
confidence: 60%
“…As displayed in Figure a, a low cell voltage of only 1.46 V was required for the electrolyzer to deliver a current density of 10 mA cm –2 which is superior to Pt/C/FF||RuO 2 /FF with 1.52 V (Figure S15, Supporting Information). The electrolyzer composed of FFNaRu and FFNaNi presented electrocatalytic performances comparable to previous materials, such as a‐RuTe 2 PNR, [ 11d ] NiFeRu‐LDH, [ 20 ] Mo‐Co 9 S 8 @C, [ 21 ] Pt‐CoS 2 /CC, [ 22 ] CoFeZr oxides/NF, [ 2a ] Ir/MoS 2 /CF, [ 23 ] Ru NP/C+NiFe LDH, [ 24 ] RuCu NSs/C, [ 25 ] and CoFe‐CDs+CoFeRu@C [ 26 ] (Figure 6b) and other reported nanomaterials (Table S3, Supporting Information). Moreover, the long‐term stability at a current density of 10 mA cm –2 showed negligible current loss after 12 h, demonstrating its superior overall water‐splitting durability (Figure 6c).…”
Section: Resultsmentioning
confidence: 60%
“…In principle, the difference in the adsorption energies between ΔG O* and ΔG OH* is suggested to be a descriptor for estimating the catalytic capability for OER. [52] Ru-SA/Ti 3 C 2 T x exhibits a lower ΔG O* −ΔG OH* value Figure 7. DFT calculation results.…”
Section: Theoretical Insights Into the Structure-activity Relationshipmentioning
confidence: 99%
“…Sun and co-workers also found the possible Mo and Co dual-sites mechanism, as the Mo-enhanced Co synergistic active sites are more competitive than the single Mo and Co sites (Figure 2d,e). [54] With the aid of surface X-ray scattering technique at welldefined catalyst surface, Shao-Horn and co-workers have experimentally identified the reaction pathways of OER at RuO 2 in acid, and proposed a modified mechanism, which is different from the traditional AEM (Figure 2f). [55] The RuO 2 exposes two different Ru sites, i.e., a coordinatively unsaturated site (CUS) bound with five O atoms and a bridge site (BRI) coordinated with six O atoms.…”
Section: Modified Reaction Pathwaysmentioning
confidence: 99%