Unconventional direct synthesis of Ni3N/Ni with N-vacancies for efficient and stable hydrogen evolution

Transition metal nitrides are a fascinating class of catalyst materials due to their superior catalytic activity, low electrical resistance, good corrosion resistance and earth abundance; however, their conventional synthesis relies on high-temperature nitridation processes in hazardous environments...

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Published inEnergy & environmental science Vol. 15; no. 1; pp. 185 - 195
Main Authors Zhang, Doudou, Li, Haobo, Riaz, Asim, Sharma, Astha, Liang, Wensheng, Wang, Yuan, Chen, Hongjun, Vora, Kaushal, Yan, Di, Su, Zhen, Tricoli, Antonio, Zhao, Chuan, Beck, Fiona J, Reuter, Karsten, Catchpole, Kylie, Karuturi, Siva
Format Journal Article
LanguageEnglish
Published Cambridge Royal Society of Chemistry 01.01.2022
Subjects
Catalysts
Catalytic activity
Chemical synthesis
Corrosion resistance
Electrical resistivity
Electrochemistry
Electrolysis
Electrolytic cells
Energy conversion
Feasibility
Hazardous areas
High temperature
Hydrogen evolution
Magnetron sputtering
Metal nitrides
Photocathodes
Pourbaix diagrams
Stability
Substrates
Transition metals
Vacancies
Wettability
Working conditions
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Abstract Transition metal nitrides are a fascinating class of catalyst materials due to their superior catalytic activity, low electrical resistance, good corrosion resistance and earth abundance; however, their conventional synthesis relies on high-temperature nitridation processes in hazardous environments. Here, we report a direct synthesis of Ni3N/Ni enriched with N-vacancies using one-step magnetron sputtering. The surface state of Ni3N(001) with 75% N-vacancies is hydrogen-terminated and exhibits four inequivalent Ni3-hollow sites. This leads to stronger H* binding compared to Ni(111), and is affirmed as the most stable surface termination under the electrochemical working conditions (pH ≈ 13.8 and E = −0.1 V) from the Pourbaix diagram. The Ni3N/Ni catalyst shows low crystallinity and good wettability and exhibits a low overpotential of 89 mV vs. RHE at 10 mA cm−2 in 1.0 M KOH with excellent stability over 3 days. This performance closely matches that of the Pt catalyst synthesized under the same conditions and surpasses that of other reported earth-abundant catalysts on planar substrates. The application of Ni3N/Ni as a cocatalyst on Si photocathodes produces an excellent ABPE of 9.3% and over 50 h stability. Moreover, its feasibility for practical application was confirmed with excellent performance on porous substrates and robustness at high operating currents in zero-gap alkaline electrolysis cells. Our work demonstrates a general approach for the feasible synthesis of other transition metal nitride catalysts for electrochemical and photoelectrochemical energy conversion applications.
AbstractList Transition metal nitrides are a fascinating class of catalyst materials due to their superior catalytic activity, low electrical resistance, good corrosion resistance and earth abundance; however, their conventional synthesis relies on high-temperature nitridation processes in hazardous environments. Here, we report a direct synthesis of Ni3N/Ni enriched with N-vacancies using one-step magnetron sputtering. The surface state of Ni3N(001) with 75% N-vacancies is hydrogen-terminated and exhibits four inequivalent Ni3-hollow sites. This leads to stronger H* binding compared to Ni(111), and is affirmed as the most stable surface termination under the electrochemical working conditions (pH ≈ 13.8 and E = −0.1 V) from the Pourbaix diagram. The Ni3N/Ni catalyst shows low crystallinity and good wettability and exhibits a low overpotential of 89 mV vs. RHE at 10 mA cm−2 in 1.0 M KOH with excellent stability over 3 days. This performance closely matches that of the Pt catalyst synthesized under the same conditions and surpasses that of other reported earth-abundant catalysts on planar substrates. The application of Ni3N/Ni as a cocatalyst on Si photocathodes produces an excellent ABPE of 9.3% and over 50 h stability. Moreover, its feasibility for practical application was confirmed with excellent performance on porous substrates and robustness at high operating currents in zero-gap alkaline electrolysis cells. Our work demonstrates a general approach for the feasible synthesis of other transition metal nitride catalysts for electrochemical and photoelectrochemical energy conversion applications.
Author Riaz, Asim
Sharma, Astha
Tricoli, Antonio
Reuter, Karsten
Karuturi, Siva
Liang, Wensheng
Wang, Yuan
Li, Haobo
Yan, Di
Su, Zhen
Beck, Fiona J
Chen, Hongjun
Zhang, Doudou
Zhao, Chuan
Catchpole, Kylie
Vora, Kaushal
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SubjectTerms Catalysts
Catalytic activity
Chemical synthesis
Corrosion resistance
Electrical resistivity
Electrochemistry
Electrolysis
Electrolytic cells
Energy conversion
Feasibility
Hazardous areas
High temperature
Hydrogen evolution
Magnetron sputtering
Metal nitrides
Photocathodes
Pourbaix diagrams
Stability
Substrates
Transition metals
Vacancies
Wettability
Working conditions
Title Unconventional direct synthesis of Ni3N/Ni with N-vacancies for efficient and stable hydrogen evolution
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