Recent Advances in Electrocatalytic Nitrate Reduction to Ammonia: Mechanism Insight and Catalyst Design

Electrocatalytic nitrate reduction reaction offers a sustainable approach to treating wastewater and synthesizing high-value ammonia under ambient conditions. However, electrocatalysts with low faradaic efficiency and selectivity severely hinder the development of nitrate-to-ammonia conversion. Herein, Ru-doped ultrasmall copper nanoparticles loaded on a carbon substrate (Cu–Ru@C) were fabricated by the pyrolysis of Cu-BTC metal–organic frameworks (MOFs). The Cu–Ru@C-0.5 catalyst exhibits a high faradaic efficiency (FE) of 90.4% at −0.6 V (vs RHE) and an ammonia yield rate of 1700.36 μg h–1mgcat. –1 at −0.9 V (vs RHE). Moreover, the nitrate conversion rate is almost 100% over varied pHs (including acid, neutral, and alkaline electrolytes) and different nitrate concentrations. The remarkable performance is attributed to the synergistic effect between Cu and Ru and the excellent conductivity of the carbon substrate. This work will open an exciting avenue to exploring MOF derivatives for ambient ammonia synthesis via selective electrocatalytic nitrate reduction.

Section: Introductionmentioning

confidence: 99%

Ru-Doped Ultrasmall Cu Nanoparticles Decorated with Carbon for Electroreduction of Nitrate to Ammonia

Li,

Wang,

Wang

et al. 2024

“…6−8 However, the nitrogen molecule utilized in ammonia synthesis exhibits significant chemical inertness, with a dissociation energy of up to 941 kJ•mol −1 for the N�N bond, thus presenting a challenge for the synthesis of ammonia. 9 Therefore, there is an urgent necessity to develop novel and efficient photocatalysts for the PNRR.…”

Section: Introductionmentioning

confidence: 99%

“…Currently, the predominant method for industrial ammonia synthesis relies on the traditional Haber–Bosch catalytic method, which necessitates high temperature and pressure to convert N 2 into NH 3 . , As a result of the extreme conditions, this process consumes over 1% of the global total energy each year and emits significant amounts of greenhouse gases, thereby exacerbating concerns regarding energy consumption and environmental concerns. , Consequently, there is an urgent necessity to develop methods that can utilize N 2 for the production of NH 3 under mild conditions. The photocatalytic nitrogen reduction reaction (PNRR) employs solar energy, a clean and renewable source of energy, as the driving force to achieve the generation of NH 3 from N 2 under ambient conditions. − However, the nitrogen molecule utilized in ammonia synthesis exhibits significant chemical inertness, with a dissociation energy of up to 941 kJ·mol –1 for the NN bond, thus presenting a challenge for the synthesis of ammonia . Therefore, there is an urgent necessity to develop novel and efficient photocatalysts for the PNRR.…”

Section: Introductionmentioning

confidence: 99%

Enhanced Photocatalytic Nitrogen Reduction via Bismuth Nanoparticle-Decorating ZnCdS Solid Solution

Meng,

Chen,

et al. 2024

Self Cite

The construction of photocatalysts with a surface plasmon resonance effect (SPR) has been demonstrated as a highly effective strategy for enhancing photocatalytic efficiency. In this paper, we synthesized a catalyst with bismuth metal loaded on ZnCdS nanospheres for an efficient photocatalytic nitrogen reduction reaction (PNRR). The SPR effect induced by Bi nanoparticles under light excitation significantly promoted the ammonia production efficiency of the photocatalyst. Under air ambient conditions with lactic acid as the sacrificial agent, the photocatalytic NH 4 + yield of 3% Bi@ZnCdS was 58.93 μmol•g −1 • h −1 , which exhibited an approximately 7.7 times that of the pure phase ZnCdS. The experimental characterization results demonstrate that the incorporation of metallic bismuth enhances the light absorption capacity of the catalyst and improves the separation efficiency of the photogenerated carriers. Theoretical calculations proved that Bi NPs provide more photogenerated electrons to convert N 2 to NH 3 for solid-solution ZnCdS. This work presents a novel concept for the development of advanced plasma nanomaterials to enhance the photocatalytic nitrogen fixation reaction.

“…Ammonia (NH 3 ) is one of the most widely used and important chemicals in the world; it is the basis of many products and processes, mainly used in agriculture, energy production, industrial production, and so forth. – The Harbor–Bosch process is the primary method used to produce NH 3 , where N 2 and H 2 react to generate NH 3 . Approximately 85% of global NH 3 production is used as agricultural fertilizer, contributing to 1.4% of global CO 2 emissions and 2% of global energy consumption. – In light of the Paris Climate Agreement’s environmental goals and the ongoing transition from fossil fuels to renewables, the chemical industry is exploring innovative ways to reduce greenhouse gas emissions associated with NH 3 production.…”

Section: Introductionmentioning

confidence: 99%

Fe and Cu Double-Doped Co₃O₄ Nanorod with Abundant Oxygen Vacancies: A High-Rate Electrocatalyst for Tandem Electroreduction of Nitrate to Ammonia

Song,

Xing,

et al. 2023

The electrochemical nitrate reduction reaction (NO3RR) is an attractive green alternative to the conventional Haber–Bosch method for the synthesis of NH3. However, this reaction is a tandem process that involves multiple steps of electrons and protons, posing a significant challenge to the efficient synthesis of NH3. Herein, we report a high-rate NO3RR electrocatalyst of Fe and Cu double-doped Co3O4 nanorod (Fe1/Cu2-Co3O4) with abundant oxygen vacancies, where the Cu preferentially catalyzes the rapid conversion of NO3 – to NO2 – and the oxygen vacancy in the Co3O4 substrate can accelerate NO2 – reduction to NH3. In addition, the introduction of Fe can efficiently capture atomic H* that promotes the dynamics of NO2 – to NH3, improving Faradaic efficiency of the produced NH3. Controlled experimental results show that the optimal electrocatalyst of Fe1/Cu2-Co3O4 exhibits good performance with high conversion (93.39%), Faradaic efficiency (98.15%), and ammonia selectivity (98.19%), which is significantly better than other Co-based materials. This work provides guidance for the rational design of high-performance NO3RR catalysts.