Synthesis of one-dimensional hierarchical mesoporous carbon for supercapacitors

Open Access

Issue		Natl Sci Open Volume 5, Number 2, 2026


Article Number		20260005
Number of page(s)		12
Section		Materials Science
DOI		https://doi.org/10.1360/nso/20260005
Published online		01 February 2026

Jiang M, Sun N, Li T, et al. Revealing the charge storage mechanism in porous carbon to achieve efficient K ion storage. Small 2024; 20: 2401478. [Article] [Google Scholar]
Li J, Li R, Wang W, et al. Ordered mesoporous crystalline frameworks toward promising energy applications. Adv Mater 2024; 36: 2311460. [Article] [Google Scholar]
Lee Y, Jo M, Kim J, et al. Versatile mesoporous microblocks prepared by pattern-induced cracking of colloidal films. Adv Mater 2023; 35: 2300952. [Article] [Google Scholar]
Zhang R, Tang C, Yang S, et al. Double-walled mesoporous hydrogen-bonded organic frameworks with high methane storage capacity. J Am Chem Soc 2025; 147: 16412-16419. [Article] [Google Scholar]
Chen S, Yuan L, Shi W. Structure-activity relationship of covalent organic frameworks (COFs) for gaseous iodine adsorption. Natl Sci Open 2024; : 20240026. [Article] [Google Scholar]
Zhang X, Hao M, Yang X, et al. Promising porous materials for ⁹⁹TcO₄-removal from nuclear wastes. Natl Sci Open 2024; : 20240007. [Article] [Google Scholar]
Zhao Y, Zhao Z. Monolayer mesoporous nanosheets with surface asymmetry via a dual-emulsion-directed monomicelle assembly. Chin J Struct Chem 2024; 43: 100238. [Article] [Google Scholar]
Han X, Zhao Y, Zhao Z. A novel hydrogen-bonded mesoporous framework nanomaterials. Chem Synth 2024; 4: 81. [Article] [Google Scholar]
Chen X, Zhao Z, Zhao Y. Uniform single-crystal mesoporous metal-organic frameworks with tunable architectures. Chin J Struct Chem 2025; 44: 100655. [Article] [Google Scholar]
Duan L, Zhao Z. Construction of zeolite loaded ultra-small Ni nanoparticle catalysts. Chin J Struct Chem 2025; 44: 100516. [Article] [Google Scholar]
Liu S, Zhao Y, Li S, et al. Design hydrophobic-internal and hydrophilic-external micropores for the preparation of microporous water. Chin J Struct Chem 2025; 44: 100701. [Article] [Google Scholar]
He J, Sun Z, Huang L, et al. Two-dimensional conductive mesopore engineering of ultrahigh content covalent sulfur-doped carbon for superior sodium storage. J Mater Chem A 2025; 13: 15736-15742. [Article] [Google Scholar]
Chen J, Li G, Bu F, et al. Tandem assembly and etching chemistry towards mesoporous conductive metal-organic frameworks for sodium storage over 50000 cycles. Angew Chem Int Ed 2025; 64: e202500287. [Article] [Google Scholar]
Wang X, Zhang S, Li M, et al. Tailored design of mesoporous metal organic framework single crystals by kinetics-mediated micelle assembly for efficient asymmetrical single-atom catalysis. Adv Mater 2025; 37: 2500370. [Article] [Google Scholar]
Zhang S, Li Y, Zhuang X, et al. Nano-metal-organic frameworks isolated in mesoporous structures. Adv Mater 2025; 37: 2418344. [Article] [Google Scholar]
Luo W, Wang Y, Wang L, et al. Silicon/mesoporous carbon/crystalline TiO₂ nanoparticles for highly stable lithium storage. ACS Nano 2016; 10: 10524-10532. [Article] [Google Scholar]
Luo R, Zhang Z, Zhang J, et al. Bimetal CoNi active sites on mesoporous carbon nanosheets to kinetically boost lithium-sulfur batteries. Small 2021; 17: 2100414. [Article] [Google Scholar]
Peng L, Hung CT, Wang S, et al. Versatile nanoemulsion assembly approach to synthesize functional mesoporous carbon nanospheres with tunable pore sizes and architectures. J Am Chem Soc 2019; 141: 7073-7080. [Article] [Google Scholar]
Peng L, Peng H, Hung CT, et al. Programmable synthesis of radially gradient-structured mesoporous carbon nanospheres with tunable core-shell architectures. Chem 2021; 7: 1020-1032. [Article] [Google Scholar]
Jiang H, Ma J, Li C. Mesoporous carbon incorporated metal oxide nanomaterials as supercapacitor electrodes. Adv Mater 2012; 24: 4196. [Article] [Google Scholar]
Yang T, Wei L, Jing L, et al. Dumbbell-shaped Bi-component mesoporous janus solid nanoparticles for biphasic interface catalysis. Angew Chem Int Ed 2017; 56: 8459-8463. [Article] [Google Scholar]
Hu K, Wang X, Hu Y, et al. Simultaneous improvement of oxygen reduction and catalyst anchoring via multiple dopants on mesoporous carbon frameworks for flexible Al-air batteries. ACS Nano 2022; 16: 19165-19173. [Article] [Google Scholar]
Liu T, Yan M, Zhou S, et al. Site-selective superassembly of a multilevel asymmetric nanomotor with wavelength-modulated propulsion mechanisms. ACS Nano 2023; 17: 14871-14882. [Article] [Google Scholar]
Xing Y, Xiu J, Zhou M, et al. Copper single-atom jellyfish-like nanomotors for enhanced tumor penetration and nanocatalytic therapy. ACS Nano 2023; 17: 6789-6799. [Article] [Google Scholar]
Zhang H, Wang H, Pan Z, et al. Zn-metal-organic framework derived ordered mesoporous carbon-based nanostructure for high-performance and universal multivalent metal ion storage. Adv Mater 2022; 34: 2206277. [Article] [Google Scholar]
Wang G, Cao Z, Gu D, et al. Nitrogen-doped ordered mesoporous carbon supported bimetallic PtCo nanoparticles for upgrading of biophenolics. Angew Chem Int Ed 2016; 55: 8850-8855. [Article] [Google Scholar]
Saleem A, Chen J, Liu M, et al. Versatile magnetic mesoporous carbon derived nano-adsorbent for synchronized toxic metal removal and bacterial disinfection from water matrices. Small 2023; 19: 2207348. [Article] [Google Scholar]
Trifonov A, Herkendell K, Tel-Vered R, et al. Enzyme-capped relay-functionalized mesoporous carbon nanoparticles: Effective bioelectrocatalytic matrices for sensing and biofuel cell applications. ACS Nano 2013; 7: 11358-11368. [Article] [Google Scholar]
Zhang X, Lv X, Qian Z, et al. Template evolution induced relay self-assembly for mesoporous carbonaceous materials via hydrothermal carbonization. ACS Nano 2024; 18: 17826-17836. [Article] [Google Scholar]
Li Y, Liu Y, Zhang K, et al. Ordered mesoporous carbon featuring single-crystal morphology and tunable pore architectures via EtOH-mediated micelle assembly. Small 2025; 21: 2502475. [Article] [Google Scholar]
Zhou S, Bi W, Zhang J, et al. Strong interaction between titanium carbonitride embedded in mesoporous carbon nanofibers and Pt enables durable oxygen reduction. Adv Mater 2024; 36: 2400808. [Article] [Google Scholar]
Wang C, Ma S, Wei Y, et al. Facile fabrication of monodisperse micron-sized dual Janus silica particles with asymmetric morphology and chemical environment. Small 2023; 19: 2208194. [Article] [Google Scholar]
Lee SH, Lee B, Kim BJ, et al. Liquid precursor-assisted chemical vapor deposition of one-dimensional van der Waals material Nb₂Se₉: Tunable growth for room-temperature gas sensors. ACS Sens 2022; 7: 1912-1918. [Article] [Google Scholar]
Luc W, Jiao F. Synthesis of nanoporous metals, oxides, carbides, and sulfides: Beyond nanocasting. Acc Chem Res 2016; 49: 1351-1358. [Article] [Google Scholar]
Adler-Abramovich L, Marco P, Arnon ZA, et al. Controlling the physical dimensions of peptide nanotubes by supramolecular polymer coassembly. ACS Nano 2016; 10: 7436-7442. [Article] [Google Scholar]
Zhao Z, Duan L, Zhao Y, et al. Constructing unique mesoporous carbon superstructures via monomicelle interface confined assembly. J Am Chem Soc 2022; 144: 11767-11777. [Article] [Google Scholar]
Zhang J, Xia C, Su Y, et al. Boosted oxygen kinetics of hierarchically mesoporous Mo₂C/C for high-current-density Zn-air battery. Small 2024; 20: 2307378. [Article] [Google Scholar]
Zou Y, Zhou X, Zhu Y, et al. sp²-Hybridized carbon-containing block copolymer templated synthesis of mesoporous semiconducting metal oxides with excellent gas sensing property. Acc Chem Res 2019; 52: 714-725. [Article] [Google Scholar]
Tian Z, Wang W, Dong C, et al. A general and scalable approach to sulfur-doped mono-/Bi-/trimetallic nanoparticles confined in mesoporous carbon. ACS Nano 2023; 17: 3889-3900. [Article] [Google Scholar]
Pandolfo AG, Hollenkamp AF. Carbon properties and their role in supercapacitors. J Power Sources 2006; 157: 11-27. [Article] [Google Scholar]
Feng LJ, Yan JY, Bian SW. Micro/mesoporous carbon nanospheres with homogeneously N,S,P-tridoped skeletons as electrodes for high-performance supercapacitors. ACS Appl Electron Mater 2023; 5: 6086-6093. [Article] [Google Scholar]
Zhao C, Sun N, Li M, et al. Sn-improving flexible carbon electrode from electrospun nanofibers for a high-performance supercapacitor. Energy Fuels 2023; 37: 13467-13475. [Article] [Google Scholar]
Zhi J, Zhao W, Liu X, et al. Highly conductive ordered mesoporous carbon based electrodes decorated by 3D graphene and 1D silver nanowire for flexible supercapacitor. Adv Funct Mater 2014; 24: 2013-2019. [Article] [Google Scholar]
Chang CH, Chen KT, Hsieh YY, et al. Crystal facet and architecture engineering of metal oxide nanonetwork anodes for high-performance potassium ion batteries and hybrid capacitors. ACS Nano 2022; 16: 1486-1501. [Article] [Google Scholar]
Qin X, Shan Z Q, Yuan Y, et al. A method for preparing carbon nanotubes or rods by hydrothermal synthesis. Chinese Patent. CN101254913A, 2008-09-03 [Google Scholar]
Zhou H, Izumi J, Asano S, et al. Fast lithium intercalation mechanism on surface-modified cathodes for lithium-ion batteries. Adv Energy Mater 2023; 13: 2302402. [Article] [Google Scholar]
Song J, Qi H, Yuan W, et al. Graphitic carbon nitride (g-C₃N₄) as an electrolyte additive boosts fast-charging and stable cycling of graphite anodes for Li-ion batteries. J Mater Chem A 2025; 13: 1964-1972. [Article] [Google Scholar]
Zheng Z, Gao Q. Hierarchical porous carbons prepared by an easy one-step carbonization and activation of phenol-formaldehyde resins with high performance for supercapacitors. J Power Sources 2011; 196: 1615-1619. [Article] [Google Scholar]
Xiong W, Liu M, Gan L, et al. A novel synthesis of mesoporous carbon microspheres for supercapacitor electrodes. J Power Sources 2011; 196: 10461-10464. [Article] [Google Scholar]
Xu F, Tang Z, Huang S, et al. Facile synthesis of ultrahigh-surface-area hollow carbon nanospheres for enhanced adsorption and energy storage. Nat Commun 2015; 6: 7221. [Article] [Google Scholar]
Wang J, Liu H, Zhang X, et al. Green synthesis of hierarchically porous carbon nanotubes as advanced materials for high-efficient energy storage. Small 2018; 14: 1703950. [Article] [Google Scholar]
Wang JG, Liu H, Zhang X, et al. Elaborate construction of N/S-co-doped carbon nanobowls for ultrahigh-power supercapacitors. J Mater Chem A 2018; 6: 17653-17661. [Article] [Google Scholar]
Huang Y, Zhou J, Gao N, et al. Synthesis of 3D reduced graphene oxide/unzipped carbon nanotubes/polyaniline composite for high-performance supercapacitors. Electrochim Acta 2018; 269: 649-656. [Article] [Google Scholar]
Xing W, Qiao SZ, Ding RG, et al. Superior electric double layer capacitors using ordered mesoporous carbons. Carbon 2006; 44: 216-224. [Article] [Google Scholar]

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