Electrochemical synthesis of ammonia using a proton conducting solid electrolyte and nickel cermet electrode

Shimoda, Naohiro; Kobayashi, Yusuke; Kimura, Yutaka; Nakagawa, Go; Satokawa, Shigeo

doi:10.2109/jcersj2.16286

Cited by 18 publications

(4 citation statements)

References 19 publications

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“…As the applied potential increased from −0.577 to −0.777 V, both the rate of ammonia formation and FE declined and finally reached a value of 1.88 × 10 –10 mol mg –1 s –1 and 0.03%, respectively. This illustrates the competition between NRR and HER predominantly at high potentials, giving rise to low FEs observed at potentials below −0.377 V. The obtained results are comparable with both iron-based (nano-Fe 2 O 3 , γ-Fe 2 O 3 , nano-Fe 3 O 4 , and CoFe 2 O 4 ) ,,− and non-iron-based catalysts (Ru/Cs + /MgO and BaCe 0.9 Y 0.1 O 3−δ ), , which were reported earlier for the systems that operate at relatively high temperatures (as shown in Table T1 in the Supporting Information).…”

Section: Results and Discussionsupporting

confidence: 85%

Electrochemical Ammonia Generation Directly from Nitrogen and Air Using an Iron-Oxide/Titania-Based Catalyst at Ambient Conditions

Manjunatha

Karajić

Goldstein

et al. 2019

ACS Appl. Mater. Interfaces

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Ammonia was produced electrochemically from nitrogen/air in aqueous alkaline electrolytes by using a Fe 2 O 3 /TiO 2 composite catalyst under room temperature and atmospheric pressure. At an applied potential of 0.023 V versus reversible hydrogen electrode, the rate of ammonia formation was 1.25 × 10 −8 mmol mg −1 s −1 at an overpotential of just 34 mV. This rate increased to 2.7 × 10 −7 mmol mg −1 s −1 at −0.577 V. The chronoamperometric experiments on Fe 2 O 3 /TiO 2 /C clearly confirmed that Fe 2 O 3 along with TiO 2 shows superior nitrogen reduction reaction activity compared to Fe 2 O 3 alone. Experimental parameters such as temperature and applied potential have a significant influence on the rate of ammonia formation. The activation energy of nitrogen reduction on the employed catalyst was found to be 25.8 kJ mol −1 . Real-time direct electrochemical mass spectrometry analysis was used to monitor the composition of the evolved gases at different electrode potentials.

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Section: Results and Discussionsupporting

confidence: 85%

Electrochemical Ammonia Generation Directly from Nitrogen and Air Using an Iron-Oxide/Titania-Based Catalyst at Ambient Conditions

Manjunatha

Karajić

Goldstein

et al. 2019

ACS Appl. Mater. Interfaces

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“…However, this design is possibly responsible for the low ammonia formation rates (≤3.0 × 10 –13 mol s –1 cm –2 ) observed in both types of electrochemical cells; more specifically, the hydrogen species (protons or hydrogen atoms) combined on the metal surface to form H 2 rather than reaching the Ru surface to produce ammonia. Other proton conductors that have been used as electrolytes in electrochemical cells for ammonia synthesis include BaCe 0.9 Y 0.1 O 3−δ and BaZr 0.8 Y 0.2 O 3−δ , and the N 2 reduction catalysts employed include Ni-BaCe 0.9 Y 0.1 O 3−δ , La 0.6 Sr 0.4 Co 0.2 Fe 0.8 O 3−δ , Ag, and Pt . In addition, the group of Tao performed a series of ammonia synthesis experiments using oxide–carbonate electrolytes and complex metal oxide electrocatalysts, in both double-chamber − and single-chamber − electrolysis cells.…”

Section: Electrocatalytic Reduction Of N2 To Ammonia At High Temperat...mentioning

confidence: 99%

Recent Advances and Challenges of Electrocatalytic N₂Reduction to Ammonia

et al. 2020

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Global ammonia production reached 175 million metric tons in 2016, 90% of which is produced from high purity N2 and H2 gases at high temperatures and pressures via the Haber–Bosch process. Reliance on natural gas for H2 production results in large energy consumption and CO2 emissions. Concerns of human-induced climate change are spurring an international scientific effort to explore new approaches to ammonia production and reduce its carbon footprint. Electrocatalytic N2 reduction to ammonia is an attractive alternative that can potentially enable ammonia synthesis under milder conditions in small-scale, distributed, and on-site electrolysis cells powered by renewable electricity generated from solar or wind sources. This review provides a comprehensive account of theoretical and experimental studies on electrochemical nitrogen fixation with a focus on the low selectivity for reduction of N2 to ammonia versus protons to H2. A detailed introduction to ammonia detection methods and the execution of control experiments is given as they are crucial to the accurate reporting of experimental findings. The main part of this review focuses on theoretical and experimental progress that has been achieved under a range of conditions. Finally, comments on current challenges and potential opportunities in this field are provided.

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“…However, the performances of H 2 O–N 2 coelectrolytic H + -SOCs have been limited in terms of NH 3 yields and evolution rates, typically less than 1% and 10 –11 mol cm –2 s –1 , respectively. − The main challenge lies in the absence of suitable cathode materials for the electrochemical nitrogen reduction reaction (ENRR), represented by the equation N 2 + 8H + + 6e – → 2NH 3 . The competing hydrogen evolution reaction (HER), with lower or similar redox overpotential compared to N 2 (ENRR: 0.092 V vs RHE, HER: 0.00 V vs RHE), exacerbates the situation.…”

Section: Introductionmentioning

confidence: 99%

Vanadium Nitride Is an Efficient Hydrogen-Diffusive Cathode for Green Ammonia Electrochemical Synthesis by Protonic Solid Oxide Electrolysis Cells

Kamitani,

Jeong,

Habazaki

et al. 2024

ACS Sustainable Chem. Eng.

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H 2 O−N 2 coelectrolysis by protonic solid oxide cells (H + -SOCs) holds great promise as it enables the sustainable production of pure ammonia gas from air and water through renewable electricity. This investigation highlights the exceptional hydrogen ion diffusivity and limited hydrogen evolution reaction (HER) activity of VN 0.9 , establishing it as a valuable cathode material for H + -SOCs. The model cells were fabricated by sputter-depositing the dense VN x film cathode (x = 0.9 and 1.1) on BaZr 0.4 Ce 0.4 Y 0.1 Yb 0.1 O 3-δ (BZCYYb4411) bulk proton electrolytes. The hydrogen pumping measurements proved that the VN 0.9 cathode allowed the bulk diffusion of the hydrogen ions while effectively retarding hydrogen evolution at its surfaces. Hence, coelectrolysis with the Ru-loaded VN 0.9 cathode achieved an ammonia Faraday efficiency and production rate of 12% and 3.8 × 10 −9 mol cm −2 , respectively, which were 2 orders of magnitude higher than those of the coelectrolytic H + -SOCs using metal cathodes. Integration of electrochemical measurements and mass spectroscopy established that the desorption of ammonia products was the rate-controlling step of the ENRR on the Ru-loaded VN 0.9 cathode. The Ru-loaded VN 0.9 cathode enabled continuous ammonia synthesis at an average rate of 2.1 × 10 −9 mol cm −2 over 50 h with periodic rest at opencircuit voltage for the catalyst reactivation by the release of chemisorbed NH 3 .

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Electrochemical synthesis of ammonia using a proton conducting solid electrolyte and nickel cermet electrode

Cited by 18 publications

References 19 publications

Electrochemical Ammonia Generation Directly from Nitrogen and Air Using an Iron-Oxide/Titania-Based Catalyst at Ambient Conditions

Electrochemical Ammonia Generation Directly from Nitrogen and Air Using an Iron-Oxide/Titania-Based Catalyst at Ambient Conditions

Recent Advances and Challenges of Electrocatalytic N₂Reduction to Ammonia

Vanadium Nitride Is an Efficient Hydrogen-Diffusive Cathode for Green Ammonia Electrochemical Synthesis by Protonic Solid Oxide Electrolysis Cells

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Electrochemical synthesis of ammonia using a proton conducting solid electrolyte and nickel cermet electrode

Cited by 18 publications

References 19 publications

Electrochemical Ammonia Generation Directly from Nitrogen and Air Using an Iron-Oxide/Titania-Based Catalyst at Ambient Conditions

Electrochemical Ammonia Generation Directly from Nitrogen and Air Using an Iron-Oxide/Titania-Based Catalyst at Ambient Conditions

Recent Advances and Challenges of Electrocatalytic N2Reduction to Ammonia

Vanadium Nitride Is an Efficient Hydrogen-Diffusive Cathode for Green Ammonia Electrochemical Synthesis by Protonic Solid Oxide Electrolysis Cells

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Product

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About

Recent Advances and Challenges of Electrocatalytic N₂Reduction to Ammonia