Catalytic Performance and Near-Surface X-ray Characterization of Titanium Hydride Electrodes for the Electrochemical Nitrate Reduction Reaction

Liu, Matthew J.; Guo, Jinyu; Hoffman, Adam S.; Stenlid, Joakim Halldin; Tang, Mingshu; Corson, Elizabeth R.; Stone, Kevin H.; Abild‐Pedersen, Frank; Bare, Simon R.; Tarpeh, William A.

doi:10.1021/jacs.2c01274

Cited by 45 publications

(62 citation statements)

References 39 publications

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“…We recommend some works once more. According to Tarpeh's group [468], the near surface of an unaltered Ti foil electrode (99.7%, 0.127 mm) changes into a composite consisting of various phases such as α-Ti, TiOx (0 < x ≤ 2), and TiHx after NO3RR. Simultaneously, the formation of crystalline titanium nitride is ruled out.…”

Section: Discussionmentioning

confidence: 99%

Recent advances in nanostructured heterogeneous catalysts for N-cycle electrocatalysis

Sun

Liang

Liu

et al. 2022

Nano Research Energy

323

229

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To restore the natural nitrogen cycle (N-cycle), artificial N-cycle electrocatalysis with flexibility, sustainability, and compatibility can convert intermittent renewable energy (e.g., wind) to harmful or value-added chemicals with minimal carbon emissions. The background of such N-cycles, such as nitrogen fixation, ammonia oxidation, and nitrate reduction, is briefly introduced here. The discussion of emerging nanostructures in various conversion reactions is focused on the architecture/compositional design, electrochemical performances, reaction mechanisms, and instructive tests. Energy device advancements for achieving more functions as well as in situ/operando characterizations toward understanding key steps are also highlighted. Furthermore, some recently proposed reactions as well as less discussed C-N coupling reactions are also summarized. We classify inorganic nitrogen sources that convert to each other under an applied voltage into three types, namely, abundant nitrogen, toxic nitrate (nitrite), and nitrogen oxides, and useful compounds such as ammonia, hydrazine, and hydroxylamine, with the goal of providing more critical insights into strategies to facilitate the development of our circular nitrogen economy.

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Section: Discussionmentioning

confidence: 99%

Recent advances in nanostructured heterogeneous catalysts for N-cycle electrocatalysis

Sun

Liang

Liu

et al. 2022

Nano Research Energy

323

229

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“…Lines are to guide the eye. Ti is excluded from (a) due to uncertainties in the work function , and surface termination (e.g., oxidation state or the presence of hydrides) , but is included in Figure S20 for reference. (c) Selectivity to nitrite at –0.4 and –0.5 V RHE against the calculated reaction free energy for nitrite reduction to nitric oxide.…”

Section: Resultsmentioning

confidence: 99%

“…High work function metals also have more anodic potentials of zero charge, providing nominally negatively charged surfaces that electrostatically attract protons. In contrast, low work function Ti has the strongest H chemisorption energy, providing H*-saturated surfaces that impede nitrate adsorption and/or hydrogen-bond-formation kinetics (i.e., PCET or hydrogenation). ,, The dependence of the nitrate rate order on Δ G H* – Δ G NO 3 – * (discussed in Section ) may provide additional context for understanding the relationship between NO 3 RR FE and work function as a future direction for the field. Differences in NO 3 RR FE are expected to be more pronounced for lower nitrate concentrations typical of, e.g., groundwater (∼1.5 mM). ,,,, …”

Section: Resultsmentioning

confidence: 99%

“…Here, we discuss the relationship between nitric oxide adsorption and dissociation energies and TM electronic structure by DFT. We limit our discussion to elements in the metallic state under the NO 3 RR conditions considered here, with consideration of Ti (uncertain surface oxidation state) 38,39 in the Supporting Information (Table S3).…”

Section: Dependence Of Intermediate Adsorbate Energy On Tm Electronicmentioning

confidence: 99%

“…To better understand the exceptional ammonium selectivity of Co, we consider the calculated reaction free energies of nitrite reduction to nitric oxide and its further dissociation (Figure 7c,d). Selectivity to nitrite nominally decreases as Δ(G NO* − 29,48 and surface termination (e.g., oxidation state or the presence of hydrides) 38,39 but is included in Figure S20 G NOd 2 − * ) decreases (Figure 7c). However, while nitrite reduction is more favorable on Ni than Co, Ni demonstrates a poorer ammonium selectivity than Co.…”

Section: Dependence Of Intermediate Adsorbate Energy On Tm Electronicmentioning

confidence: 99%

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Role of Electronic Structure on Nitrate Reduction to Ammonium: A Periodic Journey

et al. 2022

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Electrocatalysis is a promising approach to convert waste nitrate to ammonia and help close the nitrogen cycle. This renewably powered ammonia production process sources hydrogen from water (as opposed to methane in the thermal Haber−Bosch process) but requires a delicate balance between a catalyst's activity for the hydrogen evolution reaction (HER) and the nitrate reduction reaction (NO 3 RR), influencing the Faradaic efficiency (FE) and selectivity to ammonia/ammonium over other nitrogencontaining products. We measure ammonium FEs ranging from 3.6 ± 6.6% (on Ag) to 93.7 ± 0.9% (on Co) across a range of transition metals (TMs; Ti, Fe, Co, Ni, Ni 0.68 Cu 0.32 , Cu, and Ag) in buffered neutral media. To better understand these competing reaction kinetics, we develop a microkinetic model that captures the voltage-dependent nitrate rate order and illustrates its origin as competitive adsorption between nitrate and hydrogen adatoms (H*). NO 3 RR FE can be described via competition for electrons with the HER, decreasing sharply for TMs with a high work function and a correspondingly high HER activity (e.g., Ni). Ammonium selectivity nominally increases as the TM d-band center energy (E d ) approaches and overcomes the Fermi level (E F ), but is exceptionally high for Co compared to materials with similar E d . Density functional theory (DFT) calculations indicate Co maximizes ammonium selectivity via (1) strong nitrite binding enabling subsequent reduction and (2) promotion of nitric oxide dissociation, leading to selective reduction of the nitrogen adatom (N*) to ammonium.

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Emerging Applications, Developments, Prospects, and Challenges of Electrochemical Nitrate‐to‐Ammonia Conversion

Chen

Yang

et al. 2023

Adv Funct Materials

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Catalytic Performance and Near-Surface X-ray Characterization of Titanium Hydride Electrodes for the Electrochemical Nitrate Reduction Reaction

Cited by 45 publications

References 39 publications

Recent advances in nanostructured heterogeneous catalysts for N-cycle electrocatalysis

Recent advances in nanostructured heterogeneous catalysts for N-cycle electrocatalysis

Role of Electronic Structure on Nitrate Reduction to Ammonium: A Periodic Journey

Emerging Applications, Developments, Prospects, and Challenges of Electrochemical Nitrate‐to‐Ammonia Conversion

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