Ultrasmall palladium nanoparticles supported on zirconium phosphate for electrochemical CO2 reduction to ethanol

Bowen Zhong; Chengwei Hu; Kaian Sun; Wei Yan; Jiujun Zhang; Zailai Xie

doi:10.1007/s11708-025-1025-1

Front. Energy ›› 2025, Vol. 19 ›› Issue (4) : 545 -551. DOI: 10.1007/s11708-025-1025-1

RESEARCH ARTICLE

Ultrasmall palladium nanoparticles supported on zirconium phosphate for electrochemical CO₂ reduction to ethanol

Bowen Zhong ¹^,²^,^‡
, Chengwei Hu ²^,^‡
, Kaian Sun ²^,^†
, Wei Yan ²^,^†
, Jiujun Zhang ²^,^†
, Zailai Xie ¹^,^†

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Abstract

The electrochemical CO₂ reduction reaction (CO₂RR) provides a promising approach to mitigate the global greenhouse effect by converting CO₂ into high-value chemicals or fuels. Noble metal-based nanomaterials are widely regarded as efficient catalysts for CO₂RR due to their high catalytic activity and excellent stability. However, these catalysts typically favor the formation of C1 products, which have relatively low economic value. Moreover, the high cost and limited availability of noble materials necessitate strategies to reduce their usage, often by dispersing them on suitable support materials to enhance catalytic performance. In this study, a novel metal-based support, zirconium phosphate Zr₃(PO₄)₄, was used to anchor ultrasmall palladium nanoparticles (pre-ZrP-Pd). Compared to the reversible hydrogen electrode, the pre-ZrP-Pd achieved a maximum Faradaic efficiency (FE) of 92.1% for ethanol at –0.8 V versus RHE, along with a peak ethanol current density of 0.82 mA/cm². Density functional theory (DFT) calculations revealed that the strong metal-support interactions between the ZrP support and Pd nanoparticles lead to an upward shift of the Pd d-band center, enhancing the adsorption of CO* and promoting the coupling of CO and CO to produce ethanol.

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Keywords

electrochemical CO₂ reduction reaction (CO₂RR) / noble metal-based nanocatalysts / zirconium phosphate (Zr₃(PO₄)₄) support / ethanol selectivity / density functional theory (DFT) calculations

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Bowen Zhong, Chengwei Hu, Kaian Sun, Wei Yan, Jiujun Zhang, Zailai Xie. Ultrasmall palladium nanoparticles supported on zirconium phosphate for electrochemical CO₂ reduction to ethanol. Front. Energy, 2025, 19(4): 545-551 DOI:10.1007/s11708-025-1025-1

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	De Luna P, Hahn C, Higgins D. . What would it take for renewably powered electrosynthesis to displace petrochemical processes. Science, 2019, 364(6438): eaav3506

[2]	Fang W, Guo W, Lu R. . Durable CO₂ conversion in the proton-exchange membrane system. Nature, 2024, 626(7997): 86–91

[3]	Ji J, Chen J, Xiong J. . Electrocatalytic CO₂ reduction for the selective production of liquid oxygenates. Journal of Energy Chemistry, 2025, 103: 568–600

[4]	Wang J, Tang W, Zhu Z. . Stabilizing lattice oxygen of Bi₂O₃ by interstitial insertion of indium for efficient formic acid electrosynthesis. Angewandte Chemie International Edition, 2025, 64(13): e202423658

[5]	Pan F, Fang L, Li B. . N and OH-immobilized Cu₃ clusters in situ reconstructed from single-metal sites for efficient CO₂ electromethanation in bicontinuous mesochannels. Journal of the American Chemical Society, 2024, 146(2): 1423–1434

[6]	Gu J, Hsu C S, Bai L. . Atomically dispersed Fe³⁺ sites catalyze efficient CO₂ electroreduction to CO. Science, 2019, 364(6445): 1091–1094

[7]	Ding J, Bin Yang H, Ma X L. . A tin-based tandem electrocatalyst for CO₂ reduction to ethanol with 80% selectivity. Nature Energy, 2023, 8(12): 1386–1394

[8]	Cronin S P, Dulovic S, Lawrence J A. . Direct synthesis of 1-butanol with high faradaic efficiency from CO₂ utilizing cascade catalysis at a Ni-enhanced (Cr₂O₃)₃Ga₂O₃ electrocatalyst. Journal of the American Chemical Society, 2023, 145(12): 6762–6772

[9]	Jiao H, Wang C, Tian H. . Strong interaction heterointerface of NiFe oxyhydroxide/cerium oxide for efficient and stable water oxidation. Chemical Engineering Journal, 2024, 498: 155063

[10]	Tian H, Zhang Z-Y, Fang H. . Selective electrooxidation of methane to formic acid by atomically dispersed CuOx and its induced Lewis acid sites on V₂O₅ in a tubular electrode. Applied Catalysis B: Environment and Energy, 2024, 351: 124001

[11]	Pan F, Duan X, Fang L. . Long-range confinement-driven enrichment of surface oxygen-relevant species promotes C−C electrocoupling in CO₂ reduction. Advanced Energy Materials, 2023, 14(7): 2303118

[12]	Ji L, Li L, Ji X. . Highly selective electrochemical reduction of CO₂ to alcohols on an FeP nanoarray. Angewandte Chemie International Edition, 2020, 59(2): 758–762

[13]	Meng Y, Li M, Xu Y. . Boosting CO₂ electroreduction to ethanol through abundant grain boundaries in In₂S₃ nanostructures. Chemical Engineering Journal, 2023, 475: 146456

[14]	Francis S A, Velazquez J M, Ferrer I M. . Reduction of aqueous CO₂ to 1-propanol at MoS₂ electrodes. Chemistry of Materials, 2018, 30(15): 4902–4908

[15]	Yin J, Yin Z, Jin J. . A new hexagonal cobalt nanosheet catalyst for selective CO₂ conversion to ethanal. Journal of the American Chemical Society, 2021, 143(37): 15335–15343

[16]	Zheng S, Liang X, Pan J. . Multi-center cooperativity enables facile C–C coupling in electrochemical CO₂ reduction on a Ni₂P catalyst. ACS Catalysis, 2023, 13(5): 2847–2856

[17]	Zhang Z Y, Tian H, Jiao H. . SiO₂ assisted Cu⁰–Cu⁺–NH₂ composite interfaces for efficient CO₂ electroreduction to C₂₊ products. Journal of Materials Chemistry. A, Materials for Energy and Sustainability, 2024, 12(2): 1218–1232

[18]	Wang T, Duan X, Bai R. . Ni-electrocatalytic CO₂ reduction toward ethanol. Advanced Materials, 2024, 36(44): 2410125

[19]	Abdinejad M, Farzi A, Möller-Gulland R. . Eliminating redox-mediated electron transfer mechanisms on a supported molecular catalyst enables CO₂ conversion to ethanol. Nature Catalysis, 2024, 7(10): 1109–1119

[20]	Liu Z H, Liu H, Li M L. . Pd-doped InO for CO electroreduction to ethanol through CO binding regulation. ChemCatChem, 2024, 16(10): e202301700

[21]	Zhou Y, Martín A J, Dattila F. . Long-chain hydrocarbons by CO₂ electroreduction using polarized nickel catalysts. Nature Catalysis, 2022, 5(6): 545–554

[22]	Karapinar D, Huan N T, Ranjbar Sahraie N. . Electroreduction of CO₂ on single-site copper-nitrogen-doped carbon material: Selective formation of ethanol and reversible restructuration of the metal sites. Angewandte Chemie International Edition, 2019, 58(42): 15098–15103

[23]	Wang J, Gan L, Zhang Q. . A water-soluble Cu complex as molecular catalyst for electrocatalytic CO₂ reduction on graphene-based electrodes. Advanced Energy Materials, 2018, 9(3): 1803151

[24]	Ke F, Liu X, Wu J. . Selective formation of C₂ products from the electrochemical conversion of CO₂ on CuO-derived copper electrodes comprised of nanoporous ribbon arrays. Catalysis Today, 2017, 288: 18–23

[25]	Dutta A, Rahaman M, Luedi N C. . Morphology matters: Tuning the product distribution of CO₂ electroreduction on oxide-derived Cu foam catalysts. ACS Catalysis, 2016, 6(6): 3804–3814

[26]	Yin J, Yin Z, Jin J. . A new hexagonal cobalt nanosheet catalyst for selective CO₂ conversion to ethanal. Journal of the American Chemical Society, 2021, 143(37): 15335–15343

[27]	Zhu W, Liu S, Zhao K. . Activating *CO by strengthening Fe–CO π-backbonding to enhance two-carbon products formation toward CO₂ electroreduction on Fe-N₄ sites. Advanced Functional Materials, 2024, 34(38): 2402537

[28]	Ji L, Chang L, Zhang Y. . Electrocatalytic CO₂ reduction to alcohols with high selectivity over a two-dimensional Fe₂P₂S₆ nanosheet. ACS Catalysis, 2019, 9(11): 9721–9725

[29]	Wu Z Z, Zhang X L, Yang P P. . Gerhardtite as a precursor to an efficient CO-to-acetate electroreduction catalyst. Journal of the American Chemical Society, 2023, 145(44): 24338–24348