This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 3.0 License.
Kausar, A., Innovations in poly (vinyl alcohol) derived nanomaterials. Advances In materials science, 2020. 20(3): p. 5–22.Search in Google Scholar
Abdelrahman, A., F. Erchiqui, and M. Nedil, Preparation and evaluation of conductive polymeric composite from metals alloys and graphene to be future flexible antenna device. Advances in Materials Science, 2021. 21(4): p. 34–52.Search in Google Scholar
Kausar, A., Future and challenging attributes of aeronautical nanocomposites. Polymeric Nanocomposites with Carbonaceous Nanofillers for Aerospace Applications, 2022: p. 317.Search in Google Scholar
Doğan, E., Hydrogen production and its storage from solar energy. Advances in Materials Science, 2020. 20(2): p. 14–25.Search in Google Scholar
Lee, H., et al., Multifunctional polymer electrolyte membrane networks for energy storage via ion-dipole complexation in lithium metal battery. Journal of Energy Storage, 2023. 64: p. 107138.Search in Google Scholar
Çorapsiz, M.R. and H. Kahveci, A study on Li‐ion battery and supercapacitor design for hybrid energy storage systems. Energy Storage, 2023. 5(1): p. e386.Search in Google Scholar
Mohan, T. and K. Kanny, Green Nanofillers for Polymeric Materials, in Green Nanomaterials. 2020, Springer, Singapore. p. 99–138.Search in Google Scholar
Ghabussi, A., et al., Free vibration analysis of an electro-elastic GPLRC cylindrical shell surrounded by viscoelastic foundation using modified length-couple stress parameter. Mechanics Based Design of Structures and Machines, 2021. 49(5): p. 738–762.Search in Google Scholar
Huo, J., et al., Bending analysis of FG-GPLRC axisymmetric circular/annular sector plates by considering elastic foundation and horizontal friction force using 3D-poroelasticity theory. Composite Structures, 2021. 276: p. 114438.Search in Google Scholar
Ghabussi, A., et al., Frequency characteristics of a viscoelastic graphene nanoplatelet–reinforced composite circular microplate. Journal of Vibration and Control, 2021. 27(1–2): p. 101–118.Search in Google Scholar
Yang, H. A review of supercapacitor-based energy storage systems for microgrid applications. in 2018 IEEE Power & Energy Society General Meeting (PESGM). 2018. IEEE.Search in Google Scholar
Salami, B.A., et al., Graphene-based concrete: Synthesis strategies and reinforcement mechanisms in graphene-based cementitious composites (Part 1). Construction and Building Materials, 2023. 396: p. 132296.Search in Google Scholar
Huang, P.Y., et al., Grains and grain boundaries in single-layer graphene atomic patchwork quilts. Nature, 2011. 469(7330): p. 389–392.Search in Google Scholar
Geim, A.K. and K.S. Novoselov, The rise of graphene. Nature materials, 2007. 6(3): p. 183–191.Search in Google Scholar
Tour, J.M., Top-down versus bottom-up fabrication of graphene-based electronics. Chemistry of Materials, 2014. 26(1): p. 163–171.Search in Google Scholar
Zhang, Z., et al., Top-down bottom-up graphene synthesis. Nano Futures, 2019. 3(4): p. 042003.Search in Google Scholar
Wei, C., et al., Turbostratic multilayer graphene synthesis on CVD graphene template toward improving electrical performance. Japanese Journal of Applied Physics, 2019. 58(SI): p. SIIB04.Search in Google Scholar
Wang, M., et al., A Platform for Large‐Scale Graphene Electronics–CVD Growth of Single‐Layer Graphene on CVD‐Grown Hexagonal Boron Nitride. Advanced Materials, 2013. 25(19): p. 2746–2752.Search in Google Scholar
Narayanam, P.K., et al., Growth and Photocatalytic Behaviour of Transparent Reduced GO-ZnO Nanocomposite Sheets. Nanotechnology, 2019.Search in Google Scholar
Zhou, Q., et al., Scotch-tape-like exfoliation effect of graphene quantum dots for efficient preparation of graphene nanosheets in water. Applied Surface Science, 2019. 483: p. 52–59.Search in Google Scholar
Mohan, V.B., et al., Graphene-based materials and their composites: A review on production, applications and product limitations. Composites Part B: Engineering, 2018. 142: p. 200–220.Search in Google Scholar
Pei, S. and H.-M. Cheng, The reduction of graphene oxide. Carbon, 2012. 50(9): p. 3210–3228.Search in Google Scholar
Lee, H. and K.S. Lee, Interlayer distance controlled graphene, supercapacitor and method of producing the same. 2019, Google Patents.Search in Google Scholar
Panwar, N., et al., Nanocarbons for biology and medicine: sensing, imaging, and drug delivery. Chemical reviews, 2019. 119(16): p. 9559–9656.Search in Google Scholar
Han, J.T., et al., Synthesis of nanobelt-like 1-dimensional silver/nanocarbon hybrid materials for flexible and wearable electronics. Scientific reports, 2017. 7(1): p. 1–9.Search in Google Scholar
Bi, J., et al., On the Road to the Frontiers of Lithium‐ion Batteries: A Review and Outlook of Graphene Anodes. Advanced Materials, 2023: p. 2210734.Search in Google Scholar
Kumar, R., et al., A review on the current research on microwave processing techniques applied to graphene-based supercapacitor electrodes: An emerging approach beyond conventional heating. Journal of Energy Chemistry, 2022.Search in Google Scholar
Macili, A., et al., Study of hydrogen absorption in a novel three-dimensional graphene structure: Towards hydrogen storage applications. Applied Surface Science, 2023: p. 156375.Search in Google Scholar
Jin, S., et al., Three‐dimensional N‐doped carbon nanotube/graphene composite aerogel anode to develop high‐power microbial fuel cell. Energy & Environmental Materials, 2023. 6(3): p. e12373.Search in Google Scholar
Idowu, A., et al., Cryo-Assisted Extrusion Three-Dimensional Printing of Shape Memory Polymer–Graphene Composites. Journal of Manufacturing Science and Engineering, 2023. 145(4): p. 041003.Search in Google Scholar
Jiang, J., et al., Three-dimensional graphene foams with two hierarchical pore structures for metal-free electrochemical assays of dopamine and uric acid from high concentration of ascorbic acid. Journal of Electroanalytical Chemistry, 2023. 928: p. 117056.Search in Google Scholar
Lang, W., et al., Germanium decorated on three dimensional graphene networks as binder-free anode for Li-ion batteries. Journal of Power Sources, 2023. 560: p. 232706.Search in Google Scholar
Bi, J., et al., On the Road to the Frontiers of Lithium‐Ion Batteries: A Review and Outlook of Graphene Anodes. Advanced Materials, 2023. 35(16): p. 2210734.Search in Google Scholar
Ganesan, V. and A. Jayaraman, Theory and simulation studies of effective interactions, phase behavior and morphology in polymer nanocomposites. Soft Matter, 2014. 10(1): p. 13–38.Search in Google Scholar
Bhatt, S., et al., Graphene in nanomedicine: A review on nano-bio factors and antibacterial activity. Colloids and Surfaces B: Biointerfaces, 2023: p. 113323.Search in Google Scholar
Mahjoubian, M., et al., Oxidative stress, genotoxic effects, and other damages caused by chronic exposure to silver nanoparticles (ag NPs) and zinc oxide nanoparticles (ZnO NPs), and their mixtures in zebrafish (Danio rerio). Toxicology and Applied Pharmacology, 2023: p. 116569.Search in Google Scholar
José, B.J.A., M.D. Shinde, and C.A.C. Azuranahim, Zinc oxide nanostructures: review on the current updates of eco-friendly synthesis and technological applications. Nanomaterials and Energy, 2023: p. 1–13.Search in Google Scholar
Masa, A., et al., Microwave-assisted silver-doped zinc oxide towards antibacterial and mechanical performances of natural rubber latex film. Materials Today Communications, 2023. 34: p. 105475.Search in Google Scholar
Vélez, D.G.G., K.J.L. Álvarez, and M.P.R. Obando, Antibacterial Strategies: Photodynamic and Photothermal Treatments Based on Carbon-Based Materials. 2023.Search in Google Scholar
Masa, A., et al., Boosting the Antibacterial Performance of Natural Rubber Latex Foam by Introducing Silver-Doped Zinc Oxide. Polymers, 2023. 15(4): p. 1040.Search in Google Scholar
Ghazanlou, S.I., et al., Improving the properties of an Al matrix composite fabricated by laser powder bed fusion using graphene–TiO2 nanohybrid. Journal of Alloys and Compounds, 2023. 938: p. 168596.Search in Google Scholar
Chee, W., et al., Nanocomposites of graphene/polymers: a review. Rsc Advances, 2015. 5(83): p. 68014–68051.Search in Google Scholar
Naghdi, S., et al., Graphene family, and their hybrid structures for electromagnetic interference shielding applications: Recent trends and prospects. Journal of Alloys and Compounds, 2022. 900: p. 163176.Search in Google Scholar
Zhao, F., et al., Fabrication of pristine graphene-based conductive polystyrene composites towards high performance and light-weight. Composites Science and Technology, 2018. 159: p. 232–239.Search in Google Scholar
Li, C., et al., Hypercrosslinked microporous polystyrene: from synthesis to properties to applications. Materials Today Chemistry, 2023. 29: p. 101392.Search in Google Scholar
Shen, B., et al., Melt blending in situ enhances the interaction between polystyrene and graphene through π–π stacking. ACS applied materials & interfaces, 2011. 3(8): p. 3103–3109.Search in Google Scholar
Mohammadsalih, Z.G., B.J. Inkson, and B. Chen, The effect of dispersion condition on the structure and properties of polystyrene/graphene oxide nanocomposites. Polymer Composites, 2021. 42(1): p. 320–328.Search in Google Scholar
Zeng, X., J. Yang, and W. Yuan, Preparation of a poly (methyl methacrylate)-reduced graphene oxide composite with enhanced properties by a solution blending method. European polymer journal, 2012. 48(10): p. 1674–1682.Search in Google Scholar
Balasubramaniyan, R., et al., A one pot solution blending method for highly conductive poly (methyl methacrylate)-highly reduced graphene nanocomposites. Electronic Materials Letters, 2013. 9(6): p. 837–839.Search in Google Scholar
Chang, H. and H. Wu, Graphene-based nanocomposites: preparation, functionalization, and energy and environmental applications. Energy & Environmental Science, 2013. 6(12): p. 3483–3507.Search in Google Scholar
Kubota, K. and S. Komaba, practical issues and future perspective for Na-ion batteries. Journal of The Electrochemical Society, 2015. 162(14): p. A2538.Search in Google Scholar
Miao, Y., et al., Current Li-ion battery technologies in electric vehicles and opportunities for advancements. Energies, 2019. 12(6): p. 1074.Search in Google Scholar
Le, P.-A., A general introduction to lithium-ion batteries: From the first concept to the top six commercials and beyond. Journal of Electrochemical Science and Engineering, 2023. 13(4): p. 591–604.Search in Google Scholar
Bhar, M., et al., Unravelling Li-ion Storage Capability of Cobalt Oxide Anode Recovered from Spent LiCoO2 Cathode via Carbothermal Reduction. Journal of The Electrochemical Society, 2023.Search in Google Scholar
Wang, L.-H., et al., One-pot synthesis and high electrochemical performance of CuS/Cu1. 8S Nanocomposites as anodes for lithium-ion batteries. Materials, 2020. 13(17): p. 3797.Search in Google Scholar
Wang, L., et al., Lithium-air, lithium-sulfur, and sodium-ion, which secondary battery category is more environmentally friendly and promising based on footprint family indicators? Journal of Cleaner Production, 2020. 276: p. 124244.Search in Google Scholar
Kou, W., et al., A VO2/graphene oxide composite as a cathode material with high rate performance for hybrid Mg-Li batteries. Journal of Alloys and Compounds, 2022. 924: p. 166414.Search in Google Scholar
Song, Z., et al., Polymer–graphene nanocomposites as ultrafast-charge and-discharge cathodes for rechargeable lithium batteries. Nano letters, 2012. 12(5): p. 2205–2211.Search in Google Scholar
Burkhardt, S.E., et al., Li-carboxylate anode structure-property relationships from molecular modeling. Chemistry of Materials, 2013. 25(2): p. 132–141.Search in Google Scholar
Luo, Y., et al., Application of Polyaniline for Li‐Ion Batteries, Lithium–Sulfur Batteries, and Supercapacitors. ChemSusChem, 2019. 12(8): p. 1591–1611.Search in Google Scholar
Thackeray, M.M., C. Wolverton, and E.D. Isaacs, Electrical energy storage for transportation—approaching the limits of, and going beyond, lithium-ion batteries. Energy & Environmental Science, 2012. 5(7): p. 7854–7863.Search in Google Scholar
Anshori, I., et al., Facile synthesis of graphene oxide/Fe3O4 nanocomposite for electrochemical sensing on determination of dopamine. Nanocomposites, 2022. 8(1): p. 155–166.Search in Google Scholar
Kumar, R., et al., Recent progress in the synthesis of graphene and derived materials for next generation electrodes of high performance lithium ion batteries. Progress in Energy and Combustion Science, 2019. 75: p. 100786.Search in Google Scholar
Kumar, R., et al., Heteroatom doped graphene engineering for energy storage and conversion. Materials Today, 2020. 39: p. 47–65.Search in Google Scholar
Shan, Y., Y. Li, and H. Pang, Applications of tin sulfide‐based materials in lithium‐ion batteries and sodium‐ion batteries. Advanced Functional Materials, 2020. 30(23): p. 2001298.Search in Google Scholar
Joy, R., et al., Graphene: chemistry and applications for lithium-ion batteries. Electrochem, 2022. 3(1): p. 143–183.Search in Google Scholar
Li, S., et al., Vertically Aligned Carbon Nanotubes Grown on Graphene Paper as Electrodes in Lithium‐Ion Batteries and Dye‐Sensitized Solar Cells. Advanced Energy Materials, 2011. 1(4): p. 486–490.Search in Google Scholar
Barbosa, J.C., et al., Recent advances in poly (vinylidene fluoride) and its copolymers for lithium-ion battery separators. Membranes, 2018. 8(3): p. 45.Search in Google Scholar
Wang, Q., et al., Interlayer-expanded metal sulfides on graphene triggered by a molecularly self-promoting process for enhanced lithium ion storage. ACS applied materials & interfaces, 2017. 9(46): p. 40317–40323.Search in Google Scholar
Yuan, G., et al., Anchoring ZnO nanoparticles in nitrogen-doped graphene sheets as a high-performance anode material for lithium-ion batteries. Materials, 2018. 11(1): p. 96.Search in Google Scholar
Zeng, H., et al., Nitrogen-doped porous Co3O4/graphene nanocomposite for advanced lithium-ion batteries. Nanomaterials, 2019. 9(9): p. 1253.Search in Google Scholar
Dao, T.D., et al., Super-tough functionalized graphene paper as a high-capacity anode for lithium ion batteries. Chemical Engineering Journal, 2014. 250: p. 257–266.Search in Google Scholar
Jiang, M.-H., D. Cai, and N. Tan, Nitrogen-doped graphene sheets prepared from different graphene-based precursors as high capacity anode materials for lithium-ion batteries. Int. J. Electrochem. Sci, 2017. 12: p. 7154–7165.Search in Google Scholar
Wu, Z.-S., et al., Doped graphene sheets as anode materials with superhigh rate and large capacity for lithium ion batteries. ACS nano, 2011. 5(7): p. 5463–5471.Search in Google Scholar
Lu, Y., et al., Preparation of graphene oxide paper as an electrode for lithium-ion batteries based on a vacuum filtration method. International Journal of Electrochemical Science, 2017. 12(10): p. 8944–8952.Search in Google Scholar
Liang, J., et al., One-step in situ synthesis of SnO2/graphene nanocomposites and its application as an anode material for Li-ion batteries. ACS applied materials & interfaces, 2012. 4(1): p. 454–459.Search in Google Scholar
Du, T., et al., Mesoporous TiO2 spheres/graphene composite as a high-performance anode material for lithium-ion batteries. International Journal of Electrochemical Science, 2018. 13: p. 6229.Search in Google Scholar
Pandey, G.P., et al., Mesoporous hybrids of reduced graphene oxide and vanadium pentoxide for enhanced performance in lithium-ion batteries and electrochemical capacitors. ACS applied materials & interfaces, 2016. 8(14): p. 9200–9210.Search in Google Scholar
Kang, C., et al., In situ fabrication of a graphene-coated three-dimensional nickel oxide anode for high-capacity lithium-ion batteries. RSC advances, 2018. 8(14): p. 7414–7421Search in Google Scholar
Feng, Y., et al., Facile hydrothermal fabrication of ZnO–graphene hybrid anode materials with excellent lithium storage properties. Sustainable Energy & Fuels, 2017. 1(4): p. 767–779.Search in Google Scholar
Liu, J., et al., Ultrathin Li3VO4 nanoribbon/graphene sandwich-like nanostructures with ultrahigh lithium ion storage properties. Nano energy, 2015. 12: p. 709–724.Search in Google Scholar
Liu, H.-P., et al., High rate cycling performance of nanosized Li4Ti5O12/graphene composites for lithium ion batteries. Electrochimica Acta, 2016. 192: p. 38–44.Search in Google Scholar
Wang, W., et al., A high-capacity NiCo2O4@ reduced graphene oxide nanocomposite Li-ion battery anode. Journal of Alloys and Compounds, 2018. 741: p. 223–230.Search in Google Scholar
Qian, X., et al., A Ni-MOF derived graphene oxide combined Ni 3 S 2–Ni/C composite and its use in the separator coating for lithium sulfur batteries. Physical Chemistry Chemical Physics, 2023. 25(7): p. 5559–5568.Search in Google Scholar
Sultanov, F., et al., Advances of graphene-based aerogels and their modifications in lithium-sulfur batteries. Carbon, 2023. 201: p. 679–702.Search in Google Scholar
Choi, Y., et al., PVdF-HFP/exfoliated graphene oxide nanosheet hybrid separators for thermally stable Li-ion batteries. RSC advances, 2016. 6(84): p. 80706–80711.Search in Google Scholar
Liu, J., et al., Preparation and performance of a novel gel polymer electrolyte based on poly (vinylidene fluoride)/graphene separator for lithium ion battery. Electrochimica Acta, 2017. 235: p. 500–507.Search in Google Scholar
Chang, C.-H. and A. Manthiram, Covalently grafted polysulfur–graphene nanocomposites for ultrahigh sulfur-loading lithium–polysulfur batteries. ACS Energy Letters, 2017. 3(1): p. 72–77.Search in Google Scholar
Jiao, X., et al., Crumpled nitrogen-doped graphene-wrapped phosphorus composite as a promising anode for lithium-ion batteries. ACS applied materials & interfaces, 2019. 11(34): p. 30858–30864.Search in Google Scholar
Zhu, T., et al., Formation of hierarchically ordered structures in conductive polymers to enhance the performances of lithium-ion batteries. Nature Energy, 2023. 8(2): p. 129–137.Search in Google Scholar
Kausar, A., Epitome of Fullerene in Conducting Polymeric Nanocomposite—Fundamentals and Beyond. Polymer-Plastics Technology and Materials, 2023. 62(5): p. 618–631.Search in Google Scholar
Li, Z.-F., et al., Novel pyrolyzed polyaniline-grafted silicon nanoparticles encapsulated in graphene sheets as Li-ion battery anodes. ACS applied materials & interfaces, 2014. 6(8): p. 5996–6002.Search in Google Scholar
Chae, C., et al., Polyethylenimine-mediated electrostatic assembly of MnO2 nanorods on graphene oxides for use as anodes in lithium-ion batteries. ACS applied materials & interfaces, 2016. 8(18): p. 11499–11506.Search in Google Scholar
Guo, W., et al., Nitroxide radical polymer/graphene nanocomposite as an improved cathode material for rechargeable lithium batteries. Electrochimica Acta, 2012. 72: p. 81–86.Search in Google Scholar
Beladi-Mousavi, S.M., et al., High Performance Poly (viologen)–Graphene Nanocomposite Battery Materials with Puff Paste Architecture. ACS nano, 2017. 11(9): p. 8730–8740.Search in Google Scholar
Yao, X. and Y. Zhao, Three-dimensional porous graphene networks and hybrids for lithium-ion batteries and supercapacitors. Chem, 2017. 2(2): p. 171–200.Search in Google Scholar
Riyanto, E., et al., Lithium-ion battery performance improvement using two-dimensional materials. Materials Today: Proceedings, 2023.Search in Google Scholar
Wang, K.X., X.H. Li, and J.S. Chen, Surface and interface engineering of electrode materials for lithium‐ion batteries. Advanced Materials, 2015. 27(3): p. 527–545.Search in Google Scholar
Liu, J.-Y., et al., Three-dimensional graphene-based nanocomposites for high energy density Li-ion batteries. Journal of Materials Chemistry A, 2017. 5(13): p. 5977–5994.Search in Google Scholar
Han, P., et al., Lithium ion capacitors in organic electrolyte system: scientific problems, material development, and key technologies. Advanced Energy Materials, 2018. 8(26): p. 1801243.Search in Google Scholar
Padhi, A.K., K.S. Nanjundaswamy, and J.B. Goodenough, Phospho‐olivines as positive‐electrode materials for rechargeable lithium batteries. Journal of the electrochemical society, 1997. 144(4): p. 1188.Search in Google Scholar
Adams, D.J., Quantum mechanical theory diffusion in solids. An application to H in silicon and Li in LiFePO4. Solid State Ionics, 2016. 290: p. 116–120.Search in Google Scholar
Wang, C., et al., Enhancement on the selective flotation separation of carbon coated LiFePO4 and graphite electrode materials. Separation and Purification Technology, 2023. 311: p. 123252.Search in Google Scholar
Yang, J., et al., LiFePO 4–graphene as a superior cathode material for rechargeable lithium batteries: impact of stacked graphene and unfolded graphene. Energy & Environmental Science, 2013. 6(5): p. 1521–1528.Search in Google Scholar
Zhang, F., et al., Uniform incorporation of flocculent molybdenum disulfide nanostructure into three-dimensional porous graphene as an anode for high-performance lithium ion batteries and hybrid supercapacitors. ACS Applied Materials & Interfaces, 2016. 8(7): p. 4691–4699.Search in Google Scholar
Wang, D., et al., 3D V2O5-MoS2/rGO nanocomposites with enhanced peroxidase mimicking activity for sensitive colorimetric determination of H2O2 and glucose. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 2022. 269: p. 120750.Search in Google Scholar
Chao, D., et al., A V2O5/conductive‐polymer core/shell nanobelt array on three‐dimensional graphite foam: a high‐rate, ultrastable, and freestanding cathode for lithium‐ion batteries. Advanced materials, 2014. 26(33): p. 5794–5800.Search in Google Scholar
Ren, Y., et al., Microwave synthesis of SnS2 nanoflakes anchored graphene foam for flexible lithium-ion battery anodes with long cycling life. Materials Letters, 2016. 174: p. 24–27.Search in Google Scholar
Zhang, M., et al., Excellent cycling stability with high SnO2 loading on a three-dimensional graphene network for lithium ion batteries. Carbon, 2016. 102: p. 32–38.Search in Google Scholar
Jeong, J.H., et al., High-rate Li4Ti5O12/N-doped reduced graphene oxide composite using cyanamide both as nanospacer and a nitrogen doping source. Journal of Power Sources, 2016. 336: p. 376–384.Search in Google Scholar
Guo, J., et al., Flexible foams of graphene entrapped SnO2–Co3O4 nanocubes with remarkably large and fast lithium storage. Journal of Materials Chemistry A, 2016. 4(41): p. 16101–16107.Search in Google Scholar
Qu, G., et al., Graphene-coated mesoporous Co3O4 fibers as an efficient anode material for Li-ion batteries. Rsc Advances, 2016. 6(75): p. 71006–71011.Search in Google Scholar
He, J., et al., Three-dimensional hierarchically structured aerogels constructed with layered MoS2/graphene nanosheets as free-standing anodes for high-performance lithium ion batteries. Electrochimica Acta, 2016. 215: p. 12–18.Search in Google Scholar
Yuan, X.-H., et al., Research on energy management strategy of fuel cell–battery–supercapacitor passenger vehicle. Energy Reports, 2022. 8: p. 1339–1349.Search in Google Scholar
Xue, Y., et al., Transition metal oxide-based oxygen reduction reaction electrocatalysts for energy conversion systems with aqueous electrolytes. Journal of Materials Chemistry A, 2018. 6(23): p. 10595–10626.Search in Google Scholar
Mensah-Darkwa, K., et al., Supercapacitor energy storage device using biowastes: A sustainable approach to green energy. Sustainability, 2019. 11(2): p. 414.Search in Google Scholar
Wan, C., et al., A geologic architecture system‐inspired micro‐/nano‐heterostructure design for high‐performance energy storage. Advanced Energy Materials, 2018. 8(33): p. 1802388.Search in Google Scholar
Zhang, M., et al., Polyimides as Promising Materials for Lithium-Ion Batteries: A Review. Nano-Micro Letters, 2023. 15(1): p. 1–29.Search in Google Scholar
Moyseowicz, A., D. Minta, and G. Gryglewicz, Conductive Polymer/Graphene‐based Composites for Next Generation Energy Storage and Sensing Applications. ChemElectroChem, 2023. 10(9): p. e202201145.Search in Google Scholar
Kausar, A., Advances in polymer-anchored carbon nanotube foam: a review. Polymer-Plastics Technology and Materials, 2019: p. 1–14.Search in Google Scholar
de Bortoli, B.F., et al., Graphene: an overview of technology in the electric vehicles of the future. 2023.Search in Google Scholar
