Enhanced supercapacitor performance using an anodized stainless steel flexible electrode coated with an electron cyclotron resonance carbon film

Wenlei Zhang , Zhuohao Liu , Jiulong Liu , Chenyu Chai , Peidong Xue , Gang Li , Zhongyun Yuan , Lei Yang

Soft Science ›› 2026, Vol. 6 ›› Issue (1) -16.

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Soft Science ›› 2026, Vol. 6 ›› Issue (1) -16. DOI: 10.20517/ss.2025.95
Research Article
Enhanced supercapacitor performance using an anodized stainless steel flexible electrode coated with an electron cyclotron resonance carbon film
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Abstract

Electrochemically anodized stainless steel (SS) shows promise as a free-standing electrode in flexible supercapacitors due to its low cost, eco-friendly nature, and binder-free characteristics. However, unsatisfactory cycling stability limits its practical use in wearable electronics. Herein, we introduce a conductive carbon film deposited on the surface of the anodized SS electrode as a protective layer via electron cyclotron resonance sputtering. By optimizing the deposition bias voltage and deposition time, the resulting flexible electrode exhibits a specific capacitance of 271.6 mF·cm-2 at a current density of 1 mA·cm-2, representing a 2.24-fold increase over the uncoated counterpart, with 88.7% capacitance retention after 8,000 cycles. The enhanced performance is closely related to the conductivity of the surface coating, which depends on the sp2/sp3 ratio (the relative proportion of graphitic to diamond-like carbon bonding). The carbon film-coated anodized SS electrode is combined with an activated carbon on carbon cloth electrode and a gel electrolyte to produce a flexible supercapacitor. The energy storage device exhibits a wide operating potential window of 1.8 V, a high energy density of 51.70 mWh·cm-3, and a power density of 0.50 W·cm-3, accompanied by robust flexibility and mechanical stability. These findings may pave the way for the development of high-performance, flexible, and cost-effective supercapacitors compatible with large-scale semiconductor device manufacturing.

Keywords

Carbon film / anodized stainless steel / electron cyclotron resonance sputtering / cycling stability / flexible supercapacitor

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Wenlei Zhang, Zhuohao Liu, Jiulong Liu, Chenyu Chai, Peidong Xue, Gang Li, Zhongyun Yuan, Lei Yang. Enhanced supercapacitor performance using an anodized stainless steel flexible electrode coated with an electron cyclotron resonance carbon film. Soft Science, 2026, 6(1): -16 DOI:10.20517/ss.2025.95

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Yang X,Feng H.Carbon-modified NiCo2O4 as an electrode material for supercapacitors.J Phys Chem Solids2024;193:112208

[2]

Chen Y,Lu C.Flexible piezoelectric materials and strain sensors for wearable electronics and artificial intelligence applications.Chem Sci2024;15:16436-66 PMCID:PMC11440360
[3]

Wang Q,Liang X,Miao M.Flexible supercapacitors based on carbon nanotube-MnO2 nanocomposite film electrode.Chem Eng J2019;371:145-53

[4]

Song W,Lian X,Niu H.Non-preoxidation synthesis of MXene integrated flexible carbon film for supercapacitors.Chem Eng J2024;493:152804

[5]

Zhang W,Li G.Nitrogen-doped nanoporous anodic stainless steel foils towards flexible supercapacitors.Materials2022;15:1615 PMCID:PMC8879062
[6]

Li S,Peng C,Yu S.Binder-free carbon nanofiber@carbon cloth for supercapacitor and Li-ion capacitor.Appl Surf Sci2025;685:161990

[7]

Xiong C,Han J,Ni Y.Recent research progress of paper‐based supercapacitors based on cellulose.Energy Environ Mater2023;7:e12651

[8]

Kumar R,Kumar K,Kaur D.Ti–Cr–N nanopyramid/nitrogen-doped carbon quantum dot/stainless steel mesh as a flexible supercapacitor electrode.ACS Appl Nano Mater2024;7:7663-73

[9]

Zhu Y,Zhou W.Construction and performance characterization of α-Fe2O3/rGO composite for long-cycling-life supercapacitor anode.ACS Sustainable Chem Eng2017;5:5067-74

[10]

Ahmed IB,Nafati H.Supercapacitive performance of 3D-cobalt oxide (Co3O4) nanowires grown onto anodized stainless-steel substrate: effect of anodization time.Solid State Sci2024;152:107537

[11]

Feng T,Liu Z.Nanoarchitectonics of highly flexible iron-oxide nanoporous electrodes on stainless steel substrate for wearable supercapacitors.Appl Phys Rev2024;11:041414

[12]

Chai C,Liu Z.Vanadium-doped nanoporous structure on stainless steel substrate for high-performance flexible supercapacitor.J Power Sources2025;628:235933

[13]

Huang P,Pinaud S.On-chip and freestanding elastic carbon films for micro-supercapacitors.Science2016;351:691-5

[14]

Pauleau Y.Deposition and characterization of nanostructured metal/carbon composite films.Surf Coat Technol2004;180-1:313-22

[15]

Asen P,Zad AI.Transition metal ions-doped polyaniline/graphene oxide nanostructure as high performance electrode for supercapacitor applications.J Solid State Electrochem2017;22:983-96

[16]

Wang C.Cross-linked graphene layer embedded carbon film prepared using electron irradiation in ECR plasma sputtering.Surf Coat Technol2011;206:1899-904

[17]

Gao S,Lin Z,Diao D.High photoresponsivity of vertical graphene nanosheets/P-Si enhanced by electron trapping at edge quantum wells.J Phys Chem C2021;125:5392-8

[18]

Huang L,Diao D.Surface N-doped graphene sheets induced high electrocatalytic activity for selective ascorbic acid sensing.Sens Actuators B Chem2019;283:556-62

[19]

Wu ZS,Feng X.Graphene-based in-plane micro-supercapacitors with high power and energy densities.Nat Commun2013;4:2487 PMCID:PMC3778542
[20]

Kim M,Kim Y.Stainless steel: a high potential material for green electrochemical energy storage and conversion.Chem Eng J2022;440:135459

[21]

Saeki I,Furuichi R.Growth process of protective oxides formed on type 304 and 430 stainless steels at 1273 k.Corros Sci1998;40:1295-302

[22]

Dwivedi N,Zhang Z,Tripathy S.Interface engineering and controlling the friction and wear of ultrathin carbon films: high sp3 versus high sp2 carbons.Adv Funct Mater2016;26:1526-42

[23]

Mu Y,Zhao Y.In situ confined vertical growth of Co2.5Ni0.5Si2O5(OH)4 nanoarrays on rGO for an efficient oxygen evolution reaction.Nano Mater Sci2023;5:351-60

[24]

Atamny F,Dübotzky A.Surface chemistry of carbon: activation of molecular oxygen.Mol Phys1992;76:851-86

[25]

Wang Y,Fan D.Friction behaviors of DLC films in an oxygen environment: an atomistic understanding from ReaxFF simulations.Tribol Int2022;168:107448

[26]

Wang G.Oxygen-vacancy-rich cobalt–aluminium hydrotalcite structures served as high-performance supercapacitor cathode.J Mater Chem C2021;9:620-32

[27]

Long B,Wang F.Chemically-modified stainless steel mesh derived substrate-free iron-based composite as anode materials for affordable flexible energy storage devices.Electrochim Acta2018;284:271-8

[28]

Larciprete R,Petaccia L.Atomic oxygen functionalization of double walled C nanotubes.Carbon2009;47:2579-89

[29]

Liu H,Li Z,Zhu J.Fe2O3/N doped rGO anode hybridized with NiCo LDH/Co(OH)2 cathode for battery-like supercapacitor.Chem Eng J2021;403:126325

[30]

Ohkubo K,Yamada Y.Laser-induced pinpoint hydrogen evolution from benzene and water using metal free single-walled carbon nanotubes with high quantum yields.Chem Sci2015;6:666-74 PMCID:PMC5590240
[31]

Luo Z,Deng J,Zhu X.High-value utilization of mask and heavy fraction of bio-oil: from hazardous waste to biochar, bio-oil, and graphene films.J Hazard Mater2021;420:126570 PMCID:PMC9759463
[32]

Taylor CA,Chiu WK.Residual stress measurement in thin carbon films by Raman spectroscopy and nanoindentation.Thin Solid Films2003;429:190-200

[33]

Shin J,Lee K.Effect of residual stress on the Raman-spectrum analysis of tetrahedral amorphous carbon films.Appl Phys Lett2001;78:631-3

[34]

Zhang S,Xie H.A phenomenological approach for the Id/Ig ratio and sp3 fraction of magnetron sputtered a-C films.Surf Coat Technol2000;123:256-60

[35]

Dwivedi N,Malik H,Rauthan C.Correlation of sp3 and sp2 fraction of carbon with electrical, optical and nano-mechanical properties of argon-diluted diamond-like carbon films.Appl Surf Sci2011;257:6804-10

[36]

Li J,Wu Q.α‐Fe2O3 based carbon composite as pure negative electrode for application as supercapacitor.Eur J Inorg Chem2019;2019:1301-12

[37]

Zhou G,Xiao W.Porous α-Fe2O3 hollow rods/reduced graphene oxide composites templated by MoO3 nanobelts for high-performance supercapacitor applications.Molecules2024;29:1262 PMCID:PMC10974400
[38]

Jyothibasu JP.Facile, scalable, eco-friendly fabrication of high-performance flexible all-solid-state supercapacitors.Polymers2018;10:1247 PMCID:PMC6401692
[39]

Luo Q,Liu L.Triethanolamine assisted synthesis of bimetallic nickel cobalt nitride/nitrogen-doped carbon hollow nanoflowers for supercapacitor.Microstructures2023;3:2023011

[40]

Mane DB,Sawant DS.Supercapacitor performance of vanadium-doped nickel hydroxide microflowers synthesized using the chemical route.Appl Phys A2023;129:158

[41]

Huang X,Li X.Eliminating charge transfer at cathode-electrolyte interface for ultrafast kinetics in Na-ion batteries.J Am Chem Soc2024;146:29391-401

[42]

Zhan F,He Q.Metal-organic frameworks and their derivatives for metal-ion (Li, Na, K and Zn) hybrid capacitors.Chem Sci2022;13:11981-2015 PMCID:PMC9600411
[43]

Liu Y,Chen Z.CNT-threaded N-doped porous carbon film as binder-free electrode for high-capacity supercapacitor and Li–S battery.J Mater Chem A2017;5:9775-84

[44]

Zhang J,Wei T,Xu J.Hierarchical nickel cobalt phosphide @ carbon nanofibers composite microspheres: ultrahigh energy densities of electrodes for supercapacitors.Nanomaterials2023;13:2927 PMCID:PMC10675319
[45]

Mitina AA,Knyazev MA,Redkin AN.Binder-free Fe2O3/MWCNT/Al electrodes for supercapacitors.Nanomaterials2025;15:1222 PMCID:PMC12388723
[46]

Gajraj V,Ekta D.Multifunctionality exploration of NiCo2O4-rGO nanocomposites: photochemical water oxidation, methanol electro-oxidation and asymmetric supercapacitor applications.Dalton Trans2021;50:18001-15

[47]

Xia H,Lai MO.Facile synthesis of novel nanostructured MnO2 thin films and their application in supercapacitors.Nanoscale Res Lett2009;4:1035-40 PMCID:PMC2894141
[48]

Li Y,Bai G.Solvothermal synthesis of Fe2O3 loaded activated carbon as electrode materials for high-performance electrochemical capacitors.Electrochim Acta2014;134:67-75

[49]

Xu M,Li Z,Zhao J.From hydroxyl group to carbonyl group: tuning the supercapacitive performance of holey graphene.Electrochim Acta2024;473:143491

[50]

Liu L,Zhang P,Yan X.Facile synthesis of Fe2O3 nano-dots@nitrogen-doped graphene for supercapacitor electrode with ultralong cycle life in KOH electrolyte.ACS Appl Mater Interfaces2016;8:9335-44

[51]

Xu J,Sheng W.One-step synthesis of ultra-small Fe2O3 nanoparticles on carbon nanotubes at a low temperature as a high-performance anode for supercapacitors.Ionics2020;26:5211-9

[52]

Wan LM,Wu JH.Stabilizing charge storage of Fe2O3‐based electrode via phosphate ion functionalization for long cycling life.Rare Metals2022;42:39-46

[53]

Liu W,Liu J,Liu J.Flexible asymmetric supercapacitor with high energy density based on optimized MnO2 cathode and Fe2O3 anode.Chin Chem Lett2019;30:750-6

[54]

Singh U,Chakraborty AK,Saxena S.α‐Fe2O3 nanocubes as high‐performance anode for supercapacitor.Adv Sustain Syst2025;9:2400704

[55]

Duan G,Zhang C,Hou H.High mass-loading α-Fe2O3 nanoparticles anchored on nitrogen-doped wood carbon for high-energy-density supercapacitor.Chin Chem Lett2023;34:108283

[56]

Arun T,Udayabhaskar R,Akbari-Fakhrabadi A.Carbon decorated octahedral shaped Fe3O4 and α-Fe2O3 magnetic hybrid nanomaterials for next generation supercapacitor applications.Appl Surf Sci2019;485:147-57

[57]

Yan C,Lu S.Hydrothermal synthesis of vanadium doped nickel sulfide nanoflower for high-performance supercapacitor.J Alloys Compd2022;928:167189

[58]

Guo T,Pang L,Zhou T.Perspectives on working voltage of aqueous supercapacitors.Small2022;18:e2106360

[59]

Zhang Q,Yang F.High performance fiber-shaped flexible asymmetric supercapacitor based on MnO2 nanostructure composited with CuO nanowires and carbon nanotubes.Ceram Int2022;48:13996-4003

[60]

Issar S,Bansal A,Choudhary N.Li-salt assisted high performance bimetallic titanium vanadium nitride-based symmetric supercapacitor device for energy storage application.Electrochim Acta2025;535:146636

[61]

Azizi E,Shi H.Flexible polypyrrole/TiO2/MXene nanocomposite supercapacitor: a promising energy storage device.J Energy Storage2024;75:109665

[62]

Zhuang Q,Zhu Z.Facile growth of hierarchical SnO2@PPy composites on carbon cloth as all-solid-state flexible supercapacitors.J Alloys Compd2022;906:164275

[63]

Zheng D,Wang M.Robust nanoporous copper-nickel@copper-nickel oxides/metallic glass sandwiches enabling highly flexible supercapacitors.Appl Surf Sci2025;696:162995

[64]

Yao P,Shi L.Multi-level nanostructures of NiCoP/CNTs/CuO nanowire arrays/Cu foam with excellent electrochemical performance for flexible supercapacitors.J Alloys Compd2024;1009:176847

[65]

Zhao Z,Lin J.Mesoporous Co0.85Se nanowire arrays for flexible asymmetric supercapacitors with high energy and power densities.J Energy Storage2023;65:107360

[66]

Nie Y,Ji C.Achieving superior high-life-stability and stable structure for flexible fiber electrodes inspired by Bamboo rice dumpling.Electrochim Acta2023;452:142352

[67]

Dong K,Mao X.A conductive folding metamaterial via laser-induced biomimetic electrospinning.Proc Natl Acad Sci U S A2025;122:e2516066122 PMCID:PMC12595432
[68]

Wang H,Gui Y.Self-powered Sb2Te3/MoS2 heterojunction broadband photodetector on flexible substrate from visible to near infrared.Nanomaterials2023;13:1973 PMCID:PMC10343427
[69]

Li L,Lou Z.Flexible planar concentric circular micro-supercapacitor arrays for wearable gas sensing application.Nano Energy2017;41:261-8

[70]

Meng S,Cao X.Built-in piezoelectric nanogenerators promote sustainable and flexible supercapacitors: a review.Materials2023;16:6916 PMCID:PMC10647822
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