3D-printed hydrogel and Joule-heating synthesis of Pt single-atom and nanoparticle electrodes for HER

Chenyang Jiao; Yanwei Zhu; Wenjun Liu; He Zhu; Ruohan Yu; Suihao Zhang; Fan Xue; Wentao Zhang; Zhongzheng Yao; Jingqian Huang; Fujie Yu; Wei-Di Liu; Si Lan

doi:10.20517/energymater.2025.217

Energy Materials ›› 2026, Vol. 6 ›› Issue (5) -600042. DOI: 10.20517/energymater.2025.217

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3D-printed hydrogel and Joule-heating synthesis of Pt single-atom and nanoparticle electrodes for HER

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Abstract

Electrocatalysts for the hydrogen evolution reaction (HER) are critical for sustainable hydrogen production, yet simultaneously achieving high activity, atom-efficient noble-metal use and integrated fabrication remains challenging. Herein, we report a scalable strategy for fabricating integrated electrodes by combining 3D-printed hydrogel templating with ultrafast pulsed Joule heating. In detail, a 3D-printed hydrogel scaffold is transformed into an oxygen-functional hierarchical carbon support that anchors oxygen-coordinated Pt single atoms (SAs) with finely dispersed Pt nanoparticles (NPs). The resulting integrated SA/NP hybrid electrode exhibits greatly increased surface area and a micro-mesoporous architecture, which suppresses NP agglomeration, increases active-site density and improves charge transfer. First-principles calculations reveal that Pt NP primarily drives water dissociation and H^* generation, while adjacent Pt SA enhances the active-site utilization of Pt NP and facilitates OH^* transfer, together accelerating the HER pathway. As a result, the fabricated electrode delivers low overpotentials of 33, 103, and 173 mV at current densities of 10, 50, and 100 mA cm^-2, respectively, while also demonstrating remarkable durability. Beyond providing a practical route to atom-efficient HER electrodes, this integrated strategy uniquely combines a 3D-printed topological scaffold with ultrafast Joule heating to achieve synergistic Pt SA/NP sites, significantly enhancing both structural stability and catalytic kinetics, offering a great promise for next-generation energy-catalysis technologies.

Keywords

Ultrafast pulsed Joule-heating synthesis / hydrogen evolution reaction / single-atom electrocatalyst / 3D hydrogel printing

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Chenyang Jiao, Yanwei Zhu, Wenjun Liu, He Zhu, Ruohan Yu, Suihao Zhang, Fan Xue, Wentao Zhang, Zhongzheng Yao, Jingqian Huang, Fujie Yu, Wei-Di Liu, Si Lan. 3D-printed hydrogel and Joule-heating synthesis of Pt single-atom and nanoparticle electrodes for HER. Energy Materials, 2026, 6(5): -600042 DOI:10.20517/energymater.2025.217

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References

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

[1]	Han S,Tu S,Cao W.Metallic ruthenium-based nanomaterials for electrocatalytic and photocatalytic hydrogen evolution.J Mater Chem A2019;7:24691-714

[2]	Wang T,Jiao L.MOFs-derived carbon-based metal catalysts for energy-related electrocatalysis.Small2021;17:e2004398

[3]	Zhu X,Tan L.Ultrafast synthesis of tetragonal-distorted FeCoNiCuCr high-entropy alloy nanoparticles for enhanced OER performance.Chin Chem Lett2026;37:110852

[4]	Cheng N,Xu X,Dou SX.Recent development of zeolitic imidazolate frameworks (ZIFs) derived porous carbon based materials as electrocatalysts.Adv Energy Mater2018;8:1801257

[5]	Radwan A,He D.Design engineering, synthesis protocols, and energy applications of MOF-derived electrocatalysts.Nanomicro Lett2021;13:132 PMCID:PMC8169752

[6]	Shin C,Lee H.Ru-loaded pyrrolic-N-doped extensively graphitized porous carbon for high performance electrochemical hydrogen evolution.Appl Catal B Environ2023;334:122829

[7]	Vijayapradeep S,Ramakrishnan S.Novel Pt-carbon core–shell decorated hierarchical CoMo₂S₄ as efficient electrocatalysts for alkaline/seawater hydrogen evolution reaction.Chem Eng J2023;473:145348

[8]	Tian B,Ning X,Lu G.Enhancing water splitting activity by protecting hydrogen evolution activity site from poisoning of oxygen species.Appl Catal B Environ2019;249:138-46

[9]	Yin H,Zhao K.Ultrathin platinum nanowires grown on single-layered nickel hydroxide with high hydrogen evolution activity.Nat Commun2015;6:6430

[10]	Yan QQ,Chu SQ.Reversing the charge transfer between platinum and sulfur-doped carbon support for electrocatalytic hydrogen evolution.Nat Commun2019;10:4977 PMCID:PMC6823491

[11]	Yang M,Dong H.Conversion of bimetallic MOF to Ru-doped Cu electrocatalysts for efficient hydrogen evolution in alkaline media.Sci Bull2021;66:257-64

[12]	Li L,Zhu Y.Atomic ruthenium modification of nickel-cobalt alloy for enhanced alkaline hydrogen evolution.Appl Catal B Environ2023;331:122710

[13]	Wang M,Mi W.Defect‐induced electron redistribution between Pt‐N₃S₁ single atomic sites and Pt clusters for synergistic electrocatalytic hydrogen production with ultra‐high mass activity.Adv Funct Mater2024;34:2309474

[14]	Qiao B,Yang X.Single-atom catalysis of CO oxidation using Pt₁/FeO_x.Nat Chem2011;3:634-41

[15]	Sun Y,Yang W.Unraveling the multifunctional sites of Ag single-atom and nanoparticles confined within carbon nitride nanotubes for synergistic photocatalytic hydrogen evolution.Small2025;21:e2408655

[16]	Luo T,Hu Y.Fullerene lattice‐confined Ru nanoparticles and single atoms synergistically boost electrocatalytic hydrogen evolution reaction.Adv Funct Mater2023;33:2213058

[17]	Chang YH,Pourzolfaghar H,Li YY.Atomic engineering of bifunctional core-shell catalysts with dual single-atom and cobalt nanoparticles for boosting ORR and OER kinetics in Zn-air batteries.Small2025;21:e06084

[18]	Miao H,Shi Y.Ultrasmall noble metal doped Ru₂P@Ru/CNT as high-performance hydrogen evolution catalysts.ACS Sustainable Chem Eng2021;9:15063-71

[19]	Emana BB.Integrated electrodes for the nutrient removal from municipal wastewater using electrocoagulation technology.Sci Rep2025;15:28244 PMCID:PMC12318098

[20]	Chen Y,Razansky D,Qian C.WISDEM: a hybrid wireless integrated sensing detector for simultaneous EEG and MRI.Nat Methods2025;22:1944-53 PMCID:PMC12446060

[21]	Brown MA,Singh L.Direct laser writing of 3D electrodes on flexible substrates.Nat Commun2023;14:3610 PMCID:PMC10276853

[22]	Scheideler WJ.Recent advances in 3D printed electrodes - bridging the nano to mesoscale.Adv Sci2025;12:e2411951 PMCID:PMC11884523

[23]	Ma S,Xiong D.Additive manufacturing of micro-architected copper based on an ion-exchangeable hydrogel.Angew Chem Int Ed Engl2024;63:e202405135

[24]	Saccone MA,Narita K,Greer JR.Additive manufacturing of micro-architected metals via hydrogel infusion.Nature2022;612:685-90 PMCID:PMC9713131

[25]	Yao Y,Xie P.High temperature shockwave stabilized single atoms.Nat Nanotechnol2019;14:851-7

[26]	Hussain MI,Ren X,Jamil M.Recent advances in photopolymerization 3D printing of alumina-ceramic.Prog Nat Scie Mater Int2025;35:1-30

[27]	Luo M,Zhang Y.PdMo bimetallene for oxygen reduction catalysis.Nature2019;574:81-5

[28]	Ravel B.ATHENA, ARTEMIS, HEPHAESTUS: data analysis for X-ray absorption spectroscopy using IFEFFIT.J Synchrotron Radiat2005;12:537-41

[29]	Anantharaj S,Yesupatham MS.The reference electrode dilemma in energy conversion electrocatalysis: “right vs. okay vs. wrong”.J Mater Chem A2023;11:17699-709

[30]	Kresse G.Efficient iterative schemes for ab initio total-energy calculations using a plane-wave basis set.Phys Rev B Condens Matter1996;54:11169-86

[31]	Kresse G.Ab initio molecular dynamics for liquid metals.Phys Rev B Condens Matter1993;47:558-61

[32]	Hammer B,Nørskov JK.Improved adsorption energetics within density-functional theory using revised Perdew-Burke-Ernzerhof functionals.Phys Rev B1999;59:7413-21

[33]	Ma M,Wang H.Multi-interfacial engineering of hierarchical CoNi₂S₄/WS₂/Co₉S₈ hybrid frameworks for robust all-pH electrocatalytic hydrogen evolution.Appl Catal B Environ2021;297:120455

[34]	Nørskov JK,Logadottir A.Trends in the exchange current for hydrogen evolution.J Electrochem Soc2005;152:J23

[35]	El Nemr, A.; Aboughaly, R. M.; El Sikaily, A.; Masoud, M. S.; Ramadan, M. S.; Ragab, S. Microporous-activated carbons of type I adsorption isotherm derived from sugarcane bagasse impregnated with zinc chloride.Carbon Lett2022;32:229-49

[36]	Tao L,Zou Y.Charge transfer modulated activity of carbon‐based electrocatalysts.Adv Energy Mater2020;10:1901227

[37]	Wang M,Qin D.Atomically dispersed CoN₃C₁-TeN₁C₃ diatomic sites anchored in N-doped carbon as efficient bifunctional catalyst for synergistic electrocatalytic hydrogen evolution and oxygen reduction.Small2022;18:e2201974

[38]	Gong X,Zhang Q.Cobalt single atoms supported on monolithic carbon with a hollow-on-hollow architecture for efficient transfer hydrogenations.Nano Res2023;16:11358-65

[39]	Wu N,Zhang Y.Revealing the fast reaction kinetics and interfacial behaviors of CuFeS₂ hollow nanorods for durable and high-rate sodium storage.J Colloid Interface Sci2025;679:990-1000

[40]	Ma X,Xiang J.Synthesis and applications of biomass-derived electrocatalysts in water electrolysis.Int J Hydrogen Energy2024;60:845-66

[41]	Tao Y,Kaneko K.Hydrophilicity-controlled carbon aerogels with high mesoporosity.J Am Chem Soc2009;131:904-5

[42]	Liang L,Zhou H.Cobalt single atom site isolated Pt nanoparticles for efficient ORR and HER in acid media.Nano Energy2021;88:106221

[43]	Feng Y,Li S,Ma R.One stone two birds: vanadium doping as dual roles in self-reduced Pt clusters and accelerated water splitting.J Energy Chem2022;66:493-501

[44]	Feng Y,Wang M.Crystallinity effect of NiFe LDH on the growth of Pt nanoparticles and hydrogen evolution performance.J Phys Chem Lett2021;12:7221-8

[45]	Yang M,Lee S.A common single-site Pt(II)-O(OH)_x-species stabilized by sodium on "active" and "inert" supports catalyzes the water-gas shift reaction.J Am Chem Soc2015;137:3470-3

[46]	Jiang Y,Fu J.Interpenetrating triphase cobalt‐based nanocomposites as efficient bifunctional oxygen electrocatalysts for long‐lasting rechargeable Zn–air batteries.Adv Energy Mater2018;8:1702900

[47]	Shen R,Peng Q.High-concentration single atomic Pt sites on hollow CuSx for selective O₂ reduction to H₂O₂ in acid solution.Chem2019;5:2099-110

[48]	Ren Y,Zhang L.Unraveling the coordination structure-performance relationship in Pt₁/Fe₂O₃ single-atom catalyst.Nat Commun2019;10:4500 PMCID:PMC6776505

[49]	Zhu Y,Yao J.Atomically dispersed Pt-O coordination boosts highly active and durable acidic hydrogen evolution reaction.Chem Eng J2022;440:135957

[50]	Nayana K.MoS_2-x/GCD-MoS_2-x nanostructures for tuning the overpotential of Volmer-Heyrovsky reaction of electrocatalytic hydrogen evolution.Int J Hydrogen Energy2024;55:422-31