Back Article

Wei J, Li Y, Lin H, Lu X, Zhou C, et al. 2024. Copper-based electro-catalytic nitrate reduction to ammonia from water: Mechanism, preparation, and research directions. Environmental Science and Ecotechnology 20:100383

Wang S, Guo X, Gao J, Yu X, Chen Z, et al. 2026. Optimizing nitrogen-water use efficiency for nitrate reduction: spatiotemporal strategies and potential of climate-smart kiwifruit agriculture across SSP scenarios. Water Research 290:125073

van Langevelde PH, Katsounaros I, Koper MTM. 2021. Electrocatalytic nitrate reduction for sustainable ammonia production. Joule 5:290−294

Han S, Li H, Li T, Chen F, Yang R, et al. 2023. Ultralow overpotential nitrate reduction to ammonia via a three-step relay mechanism. Nature Catalysis 6:402−414

Wang H, Man S, Wang H, Presser V, Yan Q, et al. 2023. Grave-to-cradle upcycling of harmful algal biomass into atomically dispersed iron catalyst for efficient ammonia electrosynthesis from nitrate. Applied Catalysis B: Environmental 332:122778

Ge Y, Wang Y, Liu Z, Xu X, Chen Y, et al. 2025. Promoting defect formation and inhibiting hydrogen evolution by S-doping NiFe layered double hydroxide for electrocatalytic reduction of nitrate to ammonia. Water Research 274:123077

Smith C, Hill AK, Torrente-Murciano L. 2020. Current and future role of Haber-Bosch ammonia in a carbon-free energy landscape. Energy & Environmental Science 13:331−344

Ye D, Tsang SCE. 2023. Prospects and challenges of green ammonia synthesis. Nature Synthesis 2:612−623

Suryanto BHR, Du HL, Wang D, Chen J, Simonov AN, et al. 2019. Challenges and prospects in the catalysis of electroreduction of nitrogen to ammonia. Nature Catalysis 2:290−296

Cao Q, Cheng Z, Dai J, Sun T, Li G, et al. 2022. Enhanced hydrogen evolution reaction over co nanoparticles embedded N-doped carbon nanotubes electrocatalyst with Zn as an accelerant. Small 18:2204827

Shao J, Jing H, Wei P, Fu X, Pang L, et al. 2023. Electrochemical synthesis of ammonia from nitric oxide using a copper–tin alloy catalyst. Nature Energy 8:1273−1283

Liu Y, Zheng Z, Jabeen S, Liu N, Liu Y, et al. 2024. Mechanochemical route to fabricate an efficient nitrate reduction electrocatalyst. Nano Research 17:4889−4897

John J, Macfarlane DR, Simonov AN. 2023. The why and how of NO_x electroreduction to ammonia. Nature Catalysis 6:1125−1130

Gan T, Wang D. 2024. Atomically dispersed materials: ideal catalysts in atomic era. Nano Research 17:18−38

Cheng Y, Wang H, Song H, Zhang K, Waterhouse GIN, et al. 2023. Design strategies towards transition metal single atom catalysts for the oxygen reduction reaction − a review. Nano Research Energy 2:e9120082

Li P, Li R, Liu Y, Xie M, Jin Z, et al. 2023. Pulsed nitrate-to-ammonia electroreduction facilitated by tandem catalysis of nitrite intermediates. Journal of the American Chemical Society 145:6471−6479

Wang C, Hu X, Hu X, Liu X, Guan Q, et al. 2021. Typical transition metal single-atom catalysts with a metal-pyridine N structure for efficient CO₂ electroreduction. Applied Catalysis B: Environmental 296:120331

Duan X, Niu B, Wang Y, Yang Z, Ren H, et al. 2025. Regulating the electronic metal-support interaction of single-atom ruthenium catalysts for boosting chlorobenzene oxidation. Environmental Science & Technology 59:7408−7418

Long X, Huang F, Yao Z, Li P, Zhong T, et al. 2024. Advancements in electrocatalytic nitrogen reduction: a comprehensive review of single-atom catalysts for sustainable ammonia synthesis. Small 20:2400551

Peng X, Cai H, Zhou Y, Ni J, Wang X, et al. 2022. Studies of a highly active cobalt atomic cluster catalyst for ammonia synthesis. ACS Sustainable Chemistry & Engineering 10:1951−1960

Liu K, Sun Z, Peng X, Liu X, Zhang X, et al. 2025. Tailoring asymmetric RuCu dual-atom electrocatalyst toward ammonia synthesis from nitrate. Nature Communications 16:2167

Chen L, Zhang LY, Qiao S. 2025. Heterojunction-enhanced electron transfer of copper nanoparticles promotes electrocatalytic ammonia synthesis from nitric oxide. Journal of Colloid and Interface Science 692:137534

Li W, Ye Y, Zhang S, Liang C, Zhang H. 2021. A fluidized electrocatalysis approach for ammonia synthesis using oxygen vacancy-rich Co₃O₄ nanoparticles. Inorganic Chemistry Frontiers 8:4026−4034

Jeon TH, Wu ZY, Chen FY, Choi W, Alvarez PJJ, et al. 2022. Cobalt–copper nanoparticles on three-dimensional substrate for efficient ammonia synthesis via electrocatalytic nitrate reduction. The Journal of Physical Chemistry C 126:6982−6989

Zhang Y, Li J, Cai J, Yang L, Zhang T, et al. 2021. Construction of spatial effect from atomically dispersed co anchoring on subnanometer Ru cluster for enhanced N₂-to-NH₃ Conversion. ACS Catalysis 11:4430−4440

Li P, Jin Z, Fang Z, Yu G. 2021. A single-site iron catalyst with preoccupied active centers that achieves selective ammonia electrosynthesis from nitrate. Energy & Environmental Science 14:3522−3531

Tan Y, Fu J, Luo T, Liu K, Liu M. 2025. Theoretical insights into the selectivity of single-atom Fe-N-C catalysts for electrochemical NO_x Reduction. Journal of the American Chemical Society 147:4937−4944

Li R, Gao T, Wang P, Qiu W, Liu K, et al. 2023. The origin of selective nitrate-to-ammonia electroreduction on metal-free nitrogen-doped carbon aerogel catalysts. Applied Catalysis B: Environmental 331:122677

Zhou Y, Wei F, Qi H, Chai Y, Cao L, et al. 2022. Peripheral-nitrogen effects on the Ru₁ centre for highly efficient propane dehydrogenation. Nature Catalysis 5:1145−1156

Wei J, Lu X, Lin H, Liu SQ, Wei X, et al. 2026. Coupling iron oxide with iron single-atom catalyst promotes neutral electrochemical nitrate reduction from water. Water Research 289:124936

Wang Y, Cui X, Zhang J, Qiao J, Huang H, et al. 2022. Advances of atomically dispersed catalysts from single-atom to clusters in energy storage and conversion applications. Progress in Materials Science 128:100964

Jiang Y, Baimanov D, Jin S, Cheuk-Fung Law J, Zhao P, et al. 2023. In situ turning defects of exfoliated Ti₃C₂ MXene into Fenton-like catalytic active sites. Proceedings of the National Academy of Sciences of the United States of America 120:e2210211120

Qi Y, Fenes E, Ma H, Wang Y, Rout KR, et al. 2020. Cluster-size-dependent interaction between ethylene and CuCl₂ clusters supported via γ-alumina. The Journal of Physical Chemistry C 124:10430−10440

Montemore MM, Medlin JW. 2014. Scaling relations between adsorption energies for computational screening and design of catalysts. Catalysis Science & Technology 4:3748−3761

Kari J, Olsen JP, Jensen K, Badino SF, Krogh KBRM, et al. 2018. Sabatier principle for interfacial (Heterogeneous) enzyme catalysis. ACS Catalysis 8:11966−11972

Zhang W, Huang L, Guo W, Cheng Y, Zhang M, et al. 2025. Ultrafast peroxymonosulfate activation via an easily synthesized cobalt cluster for selective cobalt(IV)=O generation. Environmental Science & Technology 59:23622−23632

Li P, Xu D, Gao Y, Liu P, Liu Z, et al. 2024. Nano-confined catalysis with Co nanoparticles-encapsulated carbon nanotubes for enhanced peroxymonosulfate oxidation in secondary effluent treatment: water quality improvement and membrane fouling alleviation. Water Research 266:122357

You X, Guo Z, Jiang Q, Xia J, Wang S, et al. 2025. Magnetic-field-induced spin transition in single-atom catalysts for nitrate electrolysis to ammonia. Nano Letters 25:8704−8712

Hu Q, Li G, Huang X, Wang Z, Yang H, et al. 2019. Electronic structure engineering of single atomic Ru by Ru nanoparticles to enable enhanced activity for alkaline water reduction. Journal of Materials Chemistry A 7:19531−19538

Wang Y, Li D, Ge X, Yu J, Zhao Y, et al. 2024. Anchored cobalt nanoparticles on layered perovskites for rapid peroxymonosulfate activation in antibiotic degradation. Advanced Materials 36:2402935

Cao A, Bukas VJ, Shadravan V, Wang Z, Li H, et al. 2022. A spin promotion effect in catalytic ammonia synthesis. Nature Communications 13:2382

Su R, Li N, Liu Z, Song X, Liu W, et al. 2023. Revealing the generation of high-valent cobalt species and chlorine dioxide in the Co₃O₄-activated chlorite process: insight into the proton enhancement effect. Environmental Science & Technology 57:1882−1893

Li B, Liu Y, Hu K, Dai Q, Chen C, et al. 2024. Spin-regulated fenton-like catalysis for nonradical oxidation over metal Oxide@Carbon composites. Advanced Functional Materials 34:2401397

Liu W, Zhang C, Zhang J, Huang X, Song M, et al. 2022. Tuning the atomic configuration of Co-N-C electrocatalyst enables highly-selective H₂O₂ production in acidic media. Applied Catalysis B: Environmental 310:121312

Rao P, Wu D, Wang TJ, Li J, Deng P, et al. 2022. Single atomic cobalt electrocatalyst for efficient oxygen reduction reaction. eScience 2:399−404

Zhang BT, Yan Z, Zhao J, Chen Z, Liu Y, et al. 2023. Peroxymonocarbonate activation via Co nanoparticles confined in metal–organic frameworks for efficient antibiotic degradation in different actual water matrices. Water Research 243:120340

Kumar P, Kannimuthu K, Zeraati AS, Roy S, Wang X, et al. 2023. High-density cobalt single-atom catalysts for enhanced oxygen evolution reaction. Journal of the American Chemical Society 145:8052−8063

Zhou J, Han S, Yang R, Li T, Li W, et al. 2023. Linear adsorption enables NO selective electroreduction to hydroxylamine on single Co sites. Angewandte Chemie International Edition 62:e202305184

Niu S, Wu Y, Wang J, Gu J, Liu XZ, et al. 2025. Cobalt-oxygen coordination steering *NO hydrogenation in nitrate electroreduction. Angewandte Chemie International Edition 64:e202508227

Wang X, Chen Z, Zhao X, Yao T, Chen W, et al. 2018. Regulation of coordination number over single Co sites: triggering the efficient electroreduction of CO₂. Angewandte Chemie International Edition 57:1944−1948

Huang K, Wei Z, Liu J, Gong Z, Liu J, et al. 2022. Engineering the morphology and microenvironment of a graphene-supported Co-N-C single-atom electrocatalyst for enhanced hydrogen evolution. Small 18:2201139

Zhong J, Duan H, Cai M, Zhu Y, Wang Z, et al. 2025. Cascade electrocatalytic reduction of nitrate to ammonia using bimetallic covalent organic frameworks with tandem active sites. Angewandte Chemie International Edition 64:e202507956

Liu GC, Liu XY, Yi XH, Wang F, Chu HY, et al. 2026. Fixed-bed catalytic antibiotics detoxification through singlet oxygen-mediated nonradical oxidation: mechanisms and long-term performance. Water Research 289:124791

Chen GF, Yuan Y, Jiang H, Ren SY, Ding LX, et al. 2020. Electrochemical reduction of nitrate to ammonia via direct eight-electron transfer using a copper–molecular solid catalyst. Nature Energy 5:605−613

Xu Y, Cheng C, Zhu J, Zhang B, Wang Y, et al. 2024. Sulphur-boosted active hydrogen on copper for enhanced electrocatalytic nitrate-to-ammonia selectivity. Angewandte Chemie International Edition 63:e202400289

Li X, Xia S, Yang S, Yang X, Zheng S, et al. 2025. Asymmetric manganese sites in covalent organic frameworks for efficient nitrate-to-ammonia electrocatalysis. Angewandte Chemie International Edition 64:e202507479

Li Z, Shi Z, Ou Y, Zhong L, Yan C, et al. 2025. Pulsed electrocatalysis driven efficient ammonia synthesis by facilitating *NOOH formation and balancing *H supply. Angewandte Chemie International Edition 64:e202510287

Liu Y, Yang J, Wang Y, Zhu W, Hu K, et al. 2025. Intrinsic nanoparticle-single-atom interplays steering radical versus nonradical pathways in catalytic ozonation. Nature Communications 16:8790

Xu S, Li J, Cheng J, Li R, Wang X, et al. 2025. Single atom–cluster synergy in Ag catalysts enables chiral glyceric acid from biomass. Science Advances 11:eadz4136