Biomass-Derived Carbon and Their Composites for Supercapacitor Applications: Sources, Functions, and Mechanisms

Xi Zhu , Yi Zeng , Xianhui Zhao , Dan Liu , Weiwei Lei , Shun Lu

EcoEnergy ›› 2025, Vol. 3 ›› Issue (3) : e70000

PDF
EcoEnergy ›› 2025, Vol. 3 ›› Issue (3) : e70000 DOI: 10.1002/ece2.70000
REVIEW

Biomass-Derived Carbon and Their Composites for Supercapacitor Applications: Sources, Functions, and Mechanisms

Author information +
History +
PDF

Abstract

Biomass-derived carbons are eco-friendly and sustainable materials, making them ideal for supercapacitors due to their high surface area, excellent conductivity, cost-effectiveness, and environmental benefits. This review provides valuable insights into biomass-derived carbon and modified carbon for supercapacitors, integrating both experimental results and theoretical calculations. This review begins by discussing the origins of biomass-derived carbon in supercapacitors, including plant-based, food waste-derived, animal-origin, and microorganism-generated sources. Then, this review presents strategies to improve the performance of biomass-derived carbon in supercapacitors, including heteroatom doping, surface functionalization, and hybrid composite construction. Furthermore, this review analyzes the functions of biomass-derived carbon in supercapacitors both in its pure form and as modified materials. The review also explores composites derived from biomass-based carbon, including carbon/MXenes, carbon/MOFs, carbon/graphene, carbon/conductive polymers, carbon/transition metal oxides, and carbon/hydroxides, providing a thorough investigation. Most importantly, this review offers an innovative summary and analysis of the role of biomass-derived carbon in supercapacitors through theoretical calculations, concentrating on four key aspects: energy band structure, density of states, electron cloud density, and adsorption energy. Finally, the review concludes the future research directions for biomass carbon-based supercapacitors, including the discovery of novel biomass materials, tailoring surface functional groups, fabricating high-performance composite materials, exploring ion transfer mechanisms, and enhancing practical applications. In summary, this review offers a thorough exploration of the sources, functions, and mechanisms of biomass-derived carbon in supercapacitors, providing valuable insights for future research.

Keywords

biomass-derived carbon / energy storage / ion transfer / nanocomposites / supercapacitor

Cite this article

Download citation ▾
Xi Zhu, Yi Zeng, Xianhui Zhao, Dan Liu, Weiwei Lei, Shun Lu. Biomass-Derived Carbon and Their Composites for Supercapacitor Applications: Sources, Functions, and Mechanisms. EcoEnergy, 2025, 3(3): e70000 DOI:10.1002/ece2.70000

登录浏览全文

4963

注册一个新账户 忘记密码

References

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

Y. Lian, Z. Xu, D. Wang, et al., “Nb2O5 Quantum Dots Coated With Biomass Carbon for Ultra-Stable Lithium-Ion Supercapacitors,” Journal of Alloys and Compounds 850 (2021): 156808.
[2]

X. Liu and H. Yang, “A State-of-the-Art Review of N Self-Doped Biochar Development in Supercapacitor Applications,” Frontiers in Energy Research 11 (2023): 01–22.
[3]

S. Lu, L. Fang, X. Wang, et al., “Insights Into Activators on Biomass-Derived Carbon-Based Composites for Electrochemical Energy Storage,” Materials Today Chemistry 37 (2024): 101988.
[4]

S. Mehta, S. Jha, and H. Liang, “Lignocellulose Materials for Supercapacitor and Battery Electrodes: A Review,” Renewable & Sustainable Energy Reviews 134 (2020): 110345.
[5]

L. S. Anthony, M. Vasudevan, V. Perumal, M. Ovinis, P. B. Raja, and T. N. J. I. Edison, “Bioresource-Derived Polymer Composites for Energy Storage Applications: Brief Review,” Journal of Environmental Chemical Engineering 9, no. 5 (2021): 105832.
[6]

K. Sharma, P. Kadyan, R. K. Sharma, and S. Grover, “Heteroatom Doping in Bio-Waste Derived Activated Carbon for Enhanced Supercapacitor Performance: A Review,” Journal of Energy Storage 100 (2024): 113679.
[7]

L. Li, S. Lu, L. Fang, Y. Wei, and S. Yang, “Review on Biomass-Derived Carbon-Based Materials for Electrocatalytic Hydrogen Production: State of the Art and Outlook,” Energy & Fuels 37, no. 23 (2023): 18485–18501.
[8]

Y. Lee, H. Zhang, H.-Y. Yu, and K. C. Tam, “Electroconductive Cellulose Nanocrystals-Synthesis, Properties and Applications: A Review,” Carbohydrate Polymers 289 (2022): 119419.
[9]

S. S. Shah, M. A. Aziz, M. Al Marzooqi, A. Z. Khan, and Z. H. Yamani, “Enhanced Light-Responsive Supercapacitor Utilizing BiVO4 and Date Leaves-Derived Carbon: A Leap Towards Sustainable Energy Harvesting and Storage,” Journal of Power Sources 602 (2024): 234334.
[10]

R. N. Bulakhe, C. Ryu, J. L. Gunjakar, and J. B. In, “Chemical Route to the Synthesis of Novel Ternary CuCr2S4 Cathodes for Asymmetric Supercapacitors,” Journal of Energy Storage 56 (2022): 106175.
[11]

S. Sarmah, B. K. Kakati, A. R. Kucernak, and D. Deka, “Fabrication of Hierarchically Structured Supercapacitor Using N and S Co-Doped Activated Carbons Derived From Samanea saman Biomass,” Journal of Energy Storage 6, no. 2 (2024): e616.
[12]

G. Y. Wang, F. Y. Yi, J. H. Zhong, et al., “Towards High-Performance Supercapacitor Electrodes via Achieving 3D Cross-Network and Favorable Surface Chemistry,” ACS Applied Materials & Interfaces 14, no. 30 (2022): 34637–34648.
[13]

N. A. Saputra, G. Pari, W. Syafii, et al., “Preparation and Application of a Novel Supercapacitor From Chemically Activated Red Calliandra,” Materials Chemistry and Physics 329 (2025): 130104.
[14]

Z. Bi, Q. Kong, Y. Cao, et al., “Biomass-Derived Porous Carbon Materials With Different Dimensions for Supercapacitor Electrodes: A Review,” Journal of Materials Chemistry A 7, no. 27 (2019): 16028–16045.
[15]

Q. Jia, Y. Zhang, J. Xu, et al., “Microstructure Regulation of 1T-MoS2 via Polyethylenepolypropylene Glycol and Ethanol Treatment for High-Stability Supercapacitor,” Journal of Energy Storage 110 (2025): 115242.
[16]

Y. Zhang, J. Xu, S. Lu, et al., “Engineering Few-Layer MoS2 and rGO Heterostructure Composites for High-Performance Supercapacitors,” Advanced Composites and Hybrid Material 8, no. 1 (2025): 108.
[17]

S. Rui, Z. Li, L. Meng, et al., “Citric Acid and Plasma Treated MoS2 for High-Performance Supercapacitors,” Journal of Materials Chemistry C 13, no. 2 (2025): 849–857.
[18]

P. Gao, Y. N. Peng, S. Q. Wang, et al., “Preparation and Comparison of Polyaniline Composites With Lotus Leaf-Derived Carbon and Lotus Petiole-Derived Carbon for Supercapacitor Applications,” Electrochimica Acta 486 (2024): 144112.
[19]

L. Luo, Y. Lan, Q. Zhang, et al., “A Review on Biomass-Derived Activated Carbon as Electrode Materials for Energy Storage Supercapacitors,” Journal of Energy Storage 55 (2022): 105839.
[20]

E. Adhamash, R. Pathak, K. Chen, et al., “High-Energy Plasma Activation of Renewable Carbon for Enhanced Capacitive Performance of Supercapacitor Electrode,” Electrochimica Acta 362 (2020): 137148.
[21]

H. Jia, S. Lu, S. Shin, et al., “In Situ Anodic Electrodeposition of Two-Dimensional Conductive Metal-Organic Framework@nickel Foam for High-Performance Flexible Supercapacitor,” Journal of Power Sources 526 (2022): 231163.
[22]

Z. Zhang, S. Lu, Y. Li, et al., “Promoting Hierarchical Porous Carbon Derived From Bamboo via Copper Doping for High-Performance Supercapacitors,” Industrial Crops and Products 203 (2023): 117155.
[23]

T. Subramaniam, S. G. Krishnan, M. N. M. Ansari, N. A. Hamid, and M. Khalid, “Recent Progress on Supercapacitive Performance of Agrowaste Fibers: A Review,” Critical Reviews in Solid State and Materials Sciences 48, no. 2 (2023): 289–331.
[24]

A. Joseph, A. Mathew, and T. Thomas, “Trichosanthes Cucumerina Derived Activated Carbon: The Potential Electrode Material for High Energy Symmetric Supercapacitor,” ChemNanoMat 10, no. 12 (2024): e202400112.
[25]

Y. Yin, Q. Liu, Y. Zhao, et al., “Recent Progress and Future Directions of Biomass-Derived Hierarchical Porous Carbon: Designing, Preparation, and Supercapacitor Applications,” Energy & Fuels 37, no. 5 (2023): 3523–3554.
[26]

N. Jiang, Y. Z. Sun, X. F. Li, and J. Pan, “Research Progress of Solid Waste-Derived Carbon Materials for Electrochemical Capacitors Through Controlled Structural Regulation,” Journal of Power Sources 629 (2025): 235990.
[27]

M. Diantoro, N. I. M. Aturroifah, J. Utomo, et al., “Optimizing Sponge-Like Activated Carbon From Manihot esculenta Tubers for High-Performance Supercapacitors,” Arabian Journal of Chemistry 18, no. 1 (2025): 106068.
[28]

S. M. X. Goh, B. L. F. Chin, M. M. Huang, et al., “Harnessing Bamboo Waste for High-Performance Supercapacitors: A Comprehensive Review of Activation Methods and Applications,” Journal of Energy Storage 105 (2025): 114613.
[29]

L. Yuan, C. Shao, Q. Zhang, E. Webb, X. Zhao, and S. Lu, “Biomass-Derived Carbon Dots as Emerging Visual Platforms for Fluorescent Sensing,” Environmental Research 251 (2024): 118610.
[30]

Y. Chen, G. M. Xie, R. Sun, et al., “Preparation of N and O Doped Coal Tar Pitch Based Porous Carbon for Supercapacitor Electrode,” Materials Today Communications 39 (2024): 108814.
[31]

G. F. Cui, R. Wang, Y. Y. Guan, et al., “In-Situ Electropolymerized Polyaniline Nanoparticles Grown on Longan Shell-Derived Porous Carbon for High-Performance Supercapacitor Electrode,” Journal of Electroanalytical Chemistry 963 (2024): 118293.
[32]

S. J. Zou, M. D. Patel, L. M. Smith, E. Cha, S. Q. Shi, and W. Choi, “Pecan Shell-Derived Activated Carbon for High-Electrochemical Performance Supercapacitor Electrode,” Materials 17, no. 13 (2024): 3091.
[33]

B. Weerasuk, T. Chutimasakul, N. Prigyai, K. Nilgumhang, P. Kaeopookum, and T. Sangtawesin, “Structural and Electrochemical Evolution of Water Hyacinth-Derived Activated Carbon With Gamma Pretreatment for Supercapacitor Applications,” Materials 17, no. 13 (2024): 3233.
[34]

Y. Chen, Q. Tang, Y. Lei, C. Shen, and X. Chen, “Direct Pyrolysis Fabrication of N/O/S Self-Doping Hierarchical Porous Carbon From Platycladus orientali Leaves for Supercapacitor,” Diamond and Related Materials 148 (2024): 111412.
[35]

D. N. Ampong, P. Dzikunu, F. O. Agyemang, et al., “Facile Synthesis of Colocasia Esculenta Peels-Derived Activated Carbon for High-Performance Supercapacitor,” Energy Storage 6, no. 7 (2024): e70057.
[36]

N. Ahmad, A. Rinaldi, M. Sidoli, et al., “High Performance Quasi-Solid-State Supercapacitor Based on Activated Carbon Derived From Asparagus Waste,” Journal of Energy Storage 99 (2024): 113267.
[37]

J. J. Chen, Y. P. Wang, J. X. Xie, et al., “Cotton Fiber-Derived Ultrafine Activated Carbon Fiber for Supercapacitor Electrode: The Effect of Fibrillation,” International Journal of Biological Macromolecules 282 (2024): 137475.
[38]

K. Asare, A. Mali, M. F. Hasan, P. Agbo, A. Shahbazi, and L. Zhang, “Algae Derived Carbon From Hydrothermal Liquefaction as Sustainable Carbon Electrode Material for Supercapacitor,” C-Journal of Carbon Research 10, no. 2 (2024): 51.
[39]

S. Raviolo, M. V. Bracamonte, M. B. S. Ramanzin, et al., “Valorization of Brewer's Spent Grain via Systematic Study of KOH Activation Parameters and Its Potential Application in Energy Storage,” Biomass and Bioenergy 192 (2025): 107494.
[40]

Y. Q. Bai, Q. Z. Wang, J. N. Wang, et al., “In Situ, Nitrogen-Doped Porous Carbon Derived From Mixed Biomass as Ultra-High-Performance Supercapacitor,” Nanomaterials 14, no. 16 (2024): 1368.
[41]

X. Y. Deng, Y. C. Han, H. Y. Zhu, et al., “Jacaranda Flowers Derived Interconnected 3D Porous Carbon for High-Performance Green Supercapacitor,” Journal of Inorganic and Organometallic Polymers and Materials (2024): 1–12.
[42]

A. Nakka, J. Naradala, J. Pani, P. Rajagiri, H. Borkar, and V. R. Tumu, “Cost-Effective Synthesis of Nitrogen Self-Doped Activated Carbon With 3D Porous Honeycomb Structure for Enhanced Supercapacitor Electrode Performance,” Journal of Porous Materials 31, no. 5 (2024): 1933–1944.
[43]

X. Zhu, “Recent Advances of Transition Metal Oxides and Chalcogenides in Pseudo-Capacitors and Hybrid Capacitors: A Review of Structures, Synthetic Strategies, and Mechanism Studies,” Journal of Energy Storage 49 (2022): 104148.
[44]

X. Zhu and S. Liu, “Tremella-Like 2D Nickel-Copper Disulfide With Ultrahigh Capacity and Cyclic Retention for Hybrid Supercapacitors,” ACS Applied Materials & Interfaces 14, no. 38 (2022): 43265–43276.
[45]

K. Zhao, X. L. Sun, H. C. Fu, et al., “In Situ Construction of Metal-Organic Frameworks on Chitosan-Derived Nitrogen Self-Doped Porous Carbon for High-Performance Supercapacitors,” Journal of Colloid and Interface Science 632 (2023): 249–259.
[46]

W. Yang, Z. Yang, J. Wang, W. Lu, and W. Wang, “A Bean Catching Double Pigeons: Sonication Assisted Modification of Nb2C MXenes Composites by O-Doping Porous Biomass-Carbons for Supercapacitors and Zinc-Ion Batteries,” Journal of Energy Storage 65 (2023): 107334.
[47]

L. Cao, H. Li, X. Liu, et al., “Nitrogen, Sulfur Co-Doped Hierarchical Carbon Encapsulated in Graphene With ‘Sphere-in-Layer’ Interconnection for High-Performance Supercapacitor,” Journal of Colloid and Interface Science 599 (2021): 443–452.
[48]

X. Yang, X. Wang, B. Lu, B. Huang, Y. Xia, and G. Lin, “Biomass-Derived N, S Co-Doped Activated Carbon-Polyaniline Nanorod Composite Electrodes for High-Performance Supercapacitors,” Applied Surface Science 639 (2023): 158191.
[49]

Y. F. Yang, L. Li, B. X. Luosang, M. Shao, and X. Fu, “Decorating Flower-Like Ni(OH)2 Microspheres on Biomass-Derived Porous Carbons for Solid-State Asymmetric Supercapacitors,” ChemistrySelect 6, no. 21 (2021): 5218–5224.
[50]

J. P. Hei, L. Cheng, Y. F. Fu, et al., “Uniformly Confined V2O3 Quantum Dots Embedded in Biomass Derived Mesoporous Carbon Toward Fast and Stable Energy Storage,” Ceramics International 49, no. 10 (2023): 16002–16010.
[51]

S. Ahmed, A. Ahmed, and M. Rafat, “Nitrogen Doped Activated Carbon From Pea Skin for High Performance Supercapacitor,” Materials Research Express 5, no. 4 (2018): 045508.
[52]

A. Gopalakrishnan and S. Badhulika, “From Onion Skin Waste to Multi-Heteroatom Self-Doped Highly Wrinkled Porous Carbon Nanosheets for High-Performance Supercapacitor Device,” Journal of Energy Storage 38 (2021): 102533.
[53]

N. R. Nadar, B. Akkinepally, B. S. Harisha, et al., “Nature-Inspired Materials as Sustainable Electrodes for Energy Storage Devices: Recent Trends and Future Aspects,” Journal of Energy Storage 106 (2025): 114779.
[54]

L. Liu, X. An, Z. Tian, et al., “Biomass Derived Carbonaceous Materials With Tailored Superstructures Designed for Advanced Supercapacitor Electrodes,” Industrial Crops and Products 187 (2022): 115457.
[55]

Q. Liang, Y. Wang, Y. Yang, et al., “Nanocellulose/Two Dimensional Nanomaterials Composites for Advanced Supercapacitor Electrodes,” Frontiers in Bioengineering and Biotechnology 10 (2022): 1024453.
[56]

W. Zhang, X.-X. Ji, and M.-G. Ma, “Emerging MXene/Cellulose Composites: Design Strategies and Diverse Applications,” Chemical Engineering Journal 458 (2023): 141402.
[57]

J. Liu, W. Sun, G. Sun, X. Huang, S. Lu, and Y. Wang, “Portable Electroanalytical Platform Based on Eco-Friendly Biomass-Based Hydrogels With Bimetallic MOF Composites for Trace Acetaminophen Determination,” ACS Biomaterials Science & Engineering 11, no. 1 (2025): 649–660.
[58]

G. Murali, G. A. Babu, R. Ramesh, et al., “High-Performance Carbon Derived From Chickpea Skin via Microwave and Slow Pyrolysis for Supercapacitors,” Materials Letters 314 (2022): 131872.
[59]

L.-N. Ma, C. Shi, N. Zhao, et al., “Bacterial Cellulose Based Nano-Biomaterials for Energy Storage Applications,” Journal of Inorganic Materials 35, no. 2 (2020): 145–157.
[60]

N. Zhao, Z. Ma, W. Y. Deng, et al., “Albumen-Based Foam Protein Porous Carbon for Supercapacitor Applications,” ChemistrySelect 9, no. 28 (2024): e202400746.
[61]

B. Du, L. H. Huang, M. Shen, et al., “Diethanolamine-Assisted Preparation of Reed Flower-Derived Nitrogen-Doped Porous Carbon for Supercapacitor Electrodes,” Energy & Fuels 35, no. 22 (2021): 18789–18797.
[62]

A. Agrawal, A. Gaur, and A. Kumar, “Fabrication of Phyllanthus emblica Leaves Derived High-Performance Activated Carbon-Based Symmetric Supercapacitor With Excellent Cyclic Stability,” Journal of Energy Storage 66 (2023): 107395.
[63]

G. Zhao, Y. Li, G. Zhu, J. Shi, T. Lu, and L. Pan, “Waste Fruit Grain Orange-Derived 3D Hierarchically Porous Carbon for High-Performance All-Solid-State Supercapacitor,” Ionics 25, no. 8 (2019): 3935–3944.
[64]

S. Liu, K. Chen, Q. Wu, Y. Gao, C. Xue, and X. Dong, “Ulothrix-Derived Sulfur-Doped Porous Carbon for High-Performance Symmetric Supercapacitors,” ACS Omega 7, no. 12 (2022): 10137–10143.
[65]

L. Jiang, S. O. K. Han, M. Pirie, et al., “Seaweed Biomass Waste-Derived Carbon as an Electrode Material for Supercapacitor,” Energy & Environment 32, no. 6 (2021): 1117–1129.
[66]

R. Mehdi, S. R. Naqvi, A. H. Khoja, and R. Hussain, “Biomass Derived Activated Carbon by Chemical Surface Modification as a Source of Clean Energy for Supercapacitor Application,” Fuel 348 (2023): 128529.
[67]

K. Sun, S. Cui, L. Xiao, et al., “A Novel MoP2@Ni2P Nanosheet and an Individual Kelp-Based Porous Carbon for Assembly a Unique High Performance Asymmetric Supercapacitor,” Journal of Energy Storage 66 (2023): 107392.
[68]

Y. Sun, S. Xue, J. Sun, et al., “Silk-Derived Nitrogen-Doped Porous Carbon Electrodes With Enhanced Ionic Conductivity for High-Performance Supercapacitors,” Journal of Colloid and Interface Science 645 (2023): 297–305.
[69]

M. Rajesh, R. Manikandan, S. Park, et al., “Pinecone Biomass-Derived Activated Carbon: The Potential Electrode Material for the Development of Symmetric and Asymmetric Supercapacitors,” International Journal of Energy Research 44, no. 11 (2020): 8591–8605.
[70]

F. Jiang, Y. Zhu, Z. Liu, et al., “Novel Synthesis Route for the Preparation of Mesoporous Nitrogen-Doped Carbons From Forestry Wastes for Supercapacitors,” Surfaces and Interfaces 24 (2021): 101132.
[71]

L. Qian, F. Guo, X. Jia, et al., “Recent Development in the Synthesis of Agricultural and Forestry Biomass-Derived Porous Carbons for Supercapacitor Applications: A Review,” Ionics 26, no. 8 (2020): 3705–3723.
[72]

S. Sagadevan, T. Balakrishnan, M. Z. Rahman, et al., “Agricultural Biomass-Based Activated Carbons for Efficient and Sustainable Supercapacitors,” Journal of Energy Storage 97 (2024): 112878.
[73]

C. X. Lu, Z. S. Yu, X. K. Zhang, and X. Ma, “ZnCl2-KOH Modulation of Biomass-Derived Porous Carbon for Supercapacitors,” Energy Sources, Part A: Recovery, Utilization, and Environmental Effects 46, no. 1 (2024): 2212–2222.
[74]

C. Li, X. W. Pan, S. L. Chen, et al., “Green Synthesis of Oxygen-Enriched Tobacco Stem-Derived Porous Carbon via Pre-Oxidation and Self-Activation for High-Performance Supercapacitors,” Chemical Engineering Science 298 (2024): 120379.
[75]

X. Du, Z. Lin, Y. Zhang, et al., “Microstructural Tailoring of Porous Few-Layer Graphene-Like Biochar From Kitchen Waste Hydrolysis Residue in Molten Carbonate Medium: Structural Evolution and Conductive Additive-Free Supercapacitor Application,” Science of the Total Environment 871 (2023): 162045.
[76]

D. J. Tarimo, K. O. Oyedotun, N. F. Sylla, A. A. Mirghni, N. M. Ndiaye, and N. Manyala, “Waste Chicken Bone-Derived Porous Carbon Materials as High Performance Electrode for Supercapacitor Applications,” Journal of Energy Storage 51 (2022): 104378.
[77]

A. Singh and A. K. Ojha, “Orange Peel Derived Activated Carbon for Supercapacitor Electrode Material,” Journal of Materials Science: Materials in Electronics 34, no. 11 (2023): 1003.
[78]

J. Y. Wang, Y. L. Xu, M. F. Yan, et al., “Preparation and Application of Biomass-Based Porous Carbon With S, N, Zn, and Fe Heteroatoms Loading for Use in Supercapacitors,” Biomass and Bioenergy 156 (2022): 106301.
[79]

Y. Al Haj, S. Mousavihashemi, D. Robertson, et al., “Biowaste-Derived Electrode and Electrolyte Materials for Flexible Supercapacitors,” Chemical Engineering Journal 435 (2022): 135058.
[80]

J. Niu, M. Y. Liu, F. Xu, Z. Zhang, M. Dou, and F. Wang, “Synchronously Boosting Gravimetric and Volumetric Performance: Biomass-Derived Ternary-Doped Microporous Carbon Nanosheet Electrodes for Supercapacitors,” Carbon 140 (2018): 664–672.
[81]

M. Feng, J. P. Yan, B. He, X. Chen, and J. Sun, “Controllable Conversion of Shrimp Shells Into Chitin or Derived Carbon Material Using Acidic Deep Eutectic Solvent,” International Journal of Biological Macromolecules 193 (2021): 347–357.
[82]

H. J. Liu, X. M. Wang, W. J. Cui, Y. Q. Dou, D. Y. Zhao, and Y. Y. Xia, “Highly Ordered Mesoporous Carbon Nanofiber Arrays From a Crab Shell Biological Template and Its Application in Supercapacitors and Fuel Cells,” Journal of Materials Chemistry 20, no. 20 (2010): 4223–4230.
[83]

G. C. Blanco, M. G. D. Munhoz, A. C. Rodrigues, et al., “Process of Converting Human Hair Into Hollow Carbon Filament for Electrochemical Capacitor,” Materia-Rio De Janeiro 26, no. 2 (2021): e12964.
[84]

D. Bal Altuntas, S. Aslan, and V. Nevruzoglu, “Carbon Microrod Material Derived From Human Hair and Its Electrochemical Supercapacitor Application,” Gazi University Journal of Science 34, no. 3 (2021): 695–708.
[85]

D. B. Altuntas, S. Aslan, Y. Akyol, and V. Nevruzoğlu, “Synthesis of New Carbon Material Produced From Human Hair and Its Evaluation as Electrochemical Supercapacitor,” Energy Sources, Part A: Recovery, Utilization, and Environmental Effects 42, no. 19 (2020): 2346–2356.
[86]

J. F. Li, S. W. Ma, L. Y. Cheng, and Q. Wu, “Egg Yolk-Derived Three-Dimensional Porous Carbon for Stable Electrochemical Supercapacitors,” Materials Letters 139 (2015): 429–432.
[87]

D. Y. Zhang, M. Han, Y. B. Li, et al., “Ultra-Facile Fabrication of Phosphorus Doped Egg-Like Hierarchic Porous Carbon With Superior Supercapacitance Performance by Microwave Irradiation Combining With Self-Activation Strategy,” Journal of Power Sources 372 (2017): 260–269.
[88]

J. C. Chen, Y. Q. Liu, W. J. Li, H. Yang, and L. Xu, “The Large Electrochemical Capacitance of Nitrogen-Doped Mesoporous Carbon Derived From Egg White by Using a Zno Template,” RSC Advances 5, no. 119 (2015): 98177–98183.
[89]

L. Tang, Y. B. Zhou, X. Y. Zhou, Y. Chai, Q. Zheng, and D. Lin, “Enhancement in Electrochemical Performance of Nitrogen-Doped Hierarchical Porous Carbon-Based Supercapacitor by Optimizing Activation Temperature,” Journal of Materials Science: Materials in Electronics 30, no. 3 (2019): 2600–2609.
[90]

Y. B. Zhou, J. Ren, L. Xia, et al., “Nitrogen-Doped Hierarchical Porous Carbon Framework Derived From Waste Pig Nails for High-Performance Supercapacitors,” ChemElectroChem 4, no. 12 (2017): 3181–3187.
[91]

Q. Wang, Q. Cao, X. Y. Wang, B. Jing, H. Kuang, and L. Zhou, “A High-Capacity Carbon Prepared From Renewable Chicken Feather Biopolymer for Supercapacitors,” Journal of Power Sources 225 (2013): 101–107.
[92]

X. H. Huang, T. H. Le, M. Chen, C. Yang, and Y. Yang, “Regulating the Pore Structure and Heteroatom Doping of Hollow Carbon Fiber Based on a Trifunctional Template Method for High-Performance Lithium-Ion Capacitors,” ACS Applied Energy Materials 5, no. 3 (2022): 3034–3042.
[93]

Z. T. Bian, H. Y. Wang, X. X. Zhao, et al., “Optimized Mesopores Enable Enhanced Capacitance of Electrochemical Capacitors Using Ultrahigh Surface Area Carbon Derived From Waste Feathers,” Journal of Colloid and Interface Science 630 (2023): 115–126.
[94]

P. Wang, G. Zhang, M. Y. Li, et al., “Porous Carbon for High-Energy Density Symmetrical Supercapacitor and Lithium-Ion Hybrid Electrochemical Capacitors,” Chemical Engineering Journal 375 (2019): 122020.
[95]

P. Q. Deng, S. J. Lei, W. Wang, et al., “Conversion of Biomass Waste to Multi-Heteroatom-Doped Carbon Networks With High Surface Area and Hierarchical Porosity for Advanced Supercapacitors,” Journal of Materials Science 53, no. 20 (2018): 14536–14547.
[96]

H. Liu, W. Chen, H. Peng, et al., “Bioinspired Design of Graphene-Based N/O Self-Doped Nanoporous Carbon From Carp Scales for Advanced Zn-Ion Hybrid Supercapacitors,” Electrochimica Acta 434 (2022): 141312.
[97]

P. Sinha, K. K. Kar, and A. K. Naskar, “A Flexible, Redox-Active, Aqueous Electrolyte-Based Asymmetric Supercapacitor With High Energy Density Based on Keratin-Derived Renewable Carbon,” Advanced Materials Technologies 7, no. 11 (2022): 2200133.
[98]

K. A. Milakin, S. Gupta, O. Pop-Georgievski, et al., “Macroporous Nitrogen-Containing Carbon for Electrochemical Capacitors,” Electrochimica Acta 418 (2022): 140370.
[99]

Z. Shang, X. Y. An, L. Q. Liu, et al., “Chitin Nanofibers as Versatile Bio-Templates of Zeolitic Imidazolate Frameworks for N-Doped Hierarchically Porous Carbon Electrodes for Supercapacitor,” Carbohydrate Polymers 251 (2021): 117107.
[100]

P. P. Chang, Y. B. Cen, X. G. Li, et al., “Chitosan-Based 2D Highly Conductive Porous Carbon Nanosheet as Supercapacitor Electrode With High Voltage and Long Lifespan,” Diamond and Related Materials 130 (2022): 109514.
[101]

C. S. Kang, Y. I. Ko, K. Fujisawa, et al., “Hybridized Double-Walled Carbon Nanotubes and Activated Carbon as Free-Standing Electrode for Flexible Supercapacitor Applications,” Carbon Letters 30, no. 5 (2020): 527–534.
[102]

S. Balasubramanian and P. K. Kamaraj, “Fabrication of Natural Polymer Assisted Mesoporous Co3O4/Carbon Composites for Supercapacitors,” Electrochimica Acta 168 (2015): 50–58.
[103]

H. L. Fan and W. Z. Shen, “Gelatin-Based Microporous Carbon Nanosheets as High Performance Supercapacitor Electrodes,” ACS Sustainable Chemistry & Engineering 4, no. 3 (2016): 1328–1337.
[104]

P. Hu, D. H. Meng, G. H. Ren, R. Yan, and X. Peng, “Nitrogen-Doped Mesoporous Carbon Thin Film for Binder-Free Supercapacitor,” Applied Materials Today 5 (2016): 1–8.
[105]

J. Y. Sun, Z. F. Liu, T. Rujiralai, et al., “Tungsten Disulfide Nanoparticles Embedded in Gelatin-Derived Honeycomb-Like Nitrogen-Doped Carbon Networks With Reinforced Electrochemical Pseudocapacitance Performance,” Journal of Energy Storage 46 (2022): 103916.
[106]

A. Brandao, R. Costa, S. State, et al., “Chitins From Seafood Waste as Sustainable Porous Carbon Precursors for the Development of Eco-Friendly Supercapacitors,” Materials 16, no. 6 (2023): 2332.
[107]

H. R. Zhang, Z. X. Wang, X. X. Li, M. Zhu, and J. Zhou, “A Flake-Like N, O Co-Doped Hierarchical Porous Carbon Derived From Chitin With Enhanced Supercapacitance,” Journal of Alloys and Compounds 924 (2022): 166534.
[108]

F. B. Chen, G. Chen, P. F. Huang, et al., “High Surface Area Porous Carbon Derived From Chitosan: CH3COOH/(NH4)2HPO4 Dual-Assisted Hydrothermal Carbonization Synthesis and Its Application in Supercapacitor,” Journal of Energy Storage 71 (2023): 108180.
[109]

D. Q. Meng, C. F. Wu, Y. Z. Hu, et al., “Ingenious Synthesis of Chitosan-Based Porous Carbon Supercapacitors With Large Specific Area by a Small Amount of Potassium Hydroxide,” Journal of Energy Storage 51 (2022): 104341.
[110]

J. Jung, S. Mugobera, J. M. Ko, and K. S. Lee, “Design and Electrochemical Properties of Carbonized Pure Bacteria Electrode for Supercapacitor,” Materials Science and Engineering B-Advanced Functional Solid-State Materials 294 (2023): 116536.
[111]

Z. Liu, J. Hu, F. Shen, et al., “Trichoderma Bridges Waste Biomass and Ultra-High Specific Surface Area Carbon to Achieve a High-Performance Supercapacitor,” Journal of Power Sources 497 (2021): 229880.
[112]

L. Sun, X. Liu, J. Ma, et al., “O, N-Doping High Specific Surface Area Microporous Carbon Materials Derived From Gram-Positive Bacteria and Its Outstanding Performance for Supercapacitors,” Ceramics International 48, no. 5 (2022): 7265–7272.
[113]

X. Zhang, W. Cai, S. Zhao, et al., “Discarded Antibiotic Mycelial Residues Derived Nitrogen-Doped Porous Carbon for Electrochemical Energy Storage and Simultaneous Reduction of Antibiotic Resistance Genes(ARGs),” Environmental Research 192 (2021): 110261.
[114]

C. Qin, S. Wang, Z. Wang, et al., “Hierarchical Porous Carbon Derived From Gardenia Jasminoides Ellis Flowers for High Performance Supercapacitor,” Journal of Energy Storage 33 (2021): 102061.
[115]

X. Wei, B. P. Qiu, L. Xu, et al., “High Performance Hierarchical Porous Carbon Derived From Waste Shrimp Shell for Supercapacitor Electrodes,” Journal of Energy Storage 62 (2023): 106900.
[116]

R. J. Ramalingam, M. Sivachidambaram, J. J. Vijaya, et al., “Synthesis of Porous Activated Carbon Powder Formation From Fruit Peel and Cow Dung Waste for Modified Electrode Fabrication and Application,” Biomass and Bioenergy 142 (2020): 105800.
[117]

Y. Zou and Y. Y. Zhou, “Biomass-Derived Carbon Materials From Wood Butterfly for High-Performance Supercapacitor,” Materials Express 11, no. 3 (2021): 397–402.
[118]

R. A. Senthil, V. K. Yang, J. Q. Pan, and Y. Sun, “A Green and Economical Approach to Derive Biomass Porous Carbon From Freely Available Feather Finger Grass Flower for Advanced Symmetric Supercapacitors,” Journal of Energy Storage 35 (2021): 102287.
[119]

Z. Hu, X. Li, Z. Tu, et al., “‘Thermal Dissolution Carbon Enrichment’ Treatment of Biomass Wastes: Supercapacitor Electrode Preparation Using the Residue,” Fuel Processing Technology 205 (2020): 106430.
[120]

H. A. Hamouda, H. I. Abdu, Q. Hu, et al., “Three-Dimensional Nanoporous Activated Carbon Electrode Derived From Acacia Wood for High-Performance Supercapacitor,” Frontiers in Chemistry 10 (2022): 1024047.
[121]

M. S. Iyer and I. Rajangam, “Biomass-Derived Porous Carbon and Colour-Tunable Graphene Quantum Dots for High-Performance Supercapacitor and Selective Probe for Metal Ion Detection,” International Journal of Energy Research 46, no. 8 (2022): 10833–10843.
[122]

S. S. Gunasekaran, A. Gopalakrishnan, R. Subashchandrabose, and S. Badhulika, “Single Step, Direct Pyrolysis Assisted Synthesis of Nitrogen-Doped Porous Carbon Nanosheets Derived From Bamboo Wood for High Energy Density Asymmetric Supercapacitor,” Journal of Energy Storage 42 (2021): 103048.
[123]

Z. Shang, X. An, H. Zhang, et al., “Houttuynia-Derived Nitrogen-Doped Hierarchically Porous Carbon for High-Performance Supercapacitor,” Carbon 161 (2020): 62–70.
[124]

D. Wang, Z. Xu, Y. Lian, C. Ban, and H. Zhang, “Nitrogen Self-Doped Porous Carbon With Layered Structure Derived From Porcine Bladders for High-Performance Supercapacitors,” Journal of Colloid and Interface Science 542 (2019): 400–409.
[125]

B. Wei, T. T. Wei, C. F. Xie, K. Li, and F. Hang, “Promising Activated Carbon Derived From Sugarcane Tip as Electrode Material for High-Performance Supercapacitors,” RSC Advances 11, no. 45 (2021): 28138–28147.
[126]

E. Taer, W. Apriwandi, R. Taslim, and M. Deraman, “Novel Laurel Aromatic Evergreen Biomass Derived Hierarchical Porous Carbon Nanosheet as Sustainable Electrode for High Performance Symmetric Supercapacitor,” Journal of Energy Storage 67 (2023): 107567.
[127]

F. Zeng, Z. Meng, Z. Xu, et al., “Biomass-Derived Porous Activated Carbon for Ultra-High Performance Supercapacitor Applications and High Flux Removal of Pollutants From Water,” Ceramics International 49, no. 10 (2023): 15377–15386.
[128]

F. Wu, X. Ren, F. Tian, et al., “O and N Co-Doped Porous Carbon Derived From Crop Waste for a High-Stability All-Solid-State Symmetric Supercapacitor,” New Journal of Chemistry 46, no. 41 (2022): 19667–19674.
[129]

H. Xu, S. Zhong, C. Yuan, X. Zheng, and S. Wang, “Honeycomb-Like N, S Dual-Doped Porous Carbons Derived From Pomelo Peel by Effective Exogenous Doping Strategy for Supercapacitor Electrodes,” Diamond and Related Materials 150 (2024): 111768.
[130]

X. Ma, J. Deng, R. Zhang, and S. Li, “Hierarchical Porous Carbon Nanoarchitectonics With Honeycomb-Like and N, P Co-Doped Features for Flexible Symmetric Supercapacitors and High-Efficiency Dye Removal,” Journal of Energy Storage 65 (2023): 107272.
[131]

S. Jiao, Y. Yao, J. Zhang, et al., “Nano-Flower-Like Porous Carbon Derived From Soybean Straw for Efficient N-S Co-Doped Supercapacitors by Coupling In-Situ Heteroatom Doping With Green Activation Method,” Applied Surface Science 615 (2023): 156365.
[132]

B. Wang, Y. Li, Z. Gu, et al., “Synthesis and Design of Biomass-Derived Heteroatom-Doped Hierarchical Porous Carbon Systems for High-Voltage Supercapacitors,” Fuel Processing Technology 247 (2023): 107776.
[133]

R. Atchudan, S. Perumal, A. K. Sundramoorthy, et al., “Facile Synthesis of Functionalized Porous Carbon by Direct Pyrolysis of Anacardium Occidentale Nut-Skin Waste and Its Utilization Towards Supercapacitors,” Nanomaterials 13, no. 10 (2023): 1654.
[134]

S. Yang, Y. Cui, G. Yang, et al., “ZnCl2 Induced Hierarchical Porous Carbon for Zinc-Ion Hybrid Supercapacitors,” Journal of Power Sources 554 (2023): 232347.
[135]

Y. Sun, J. P. Zhang, G. Yang, and Z. Li, “Production of Activated Carbon by H3PO4 Activation Treatment of Corncob and Its Performance in Removing Nitrobenzene From Water,” Environmental Progress 26, no. 1 (2007): 78–85.
[136]

K.-C. Lee, M. S. W. Lim, Z.-Y. Hong, et al., “Coconut Shell-Derived Activated Carbon for High-Performance Solid-State Supercapacitors,” Energies 14, no. 15 (2021): 4546.
[137]

O. Üner and Y. Bayrak, “The Effect of Carbonization Temperature, Carbonization Time and Impregnation Ratio on the Properties of Activated Carbon Produced From Arundo Donax,” Microporous and Mesoporous Materials 268 (2018): 225–234.
[138]

J. Chen, J. Liu, D. Wu, et al., “Improving the Supercapacitor Performance of Activated Carbon Materials Derived From Pretreated Rice Husk,” Journal of Energy Storage 44 (2021): 103432.
[139]

C. Long, X. Chen, L. Jiang, L. Zhi, and Z. Fan, “Porous Layer-Stacking Carbon Derived From In-Built Template in Biomass for High Volumetric Performance Supercapacitors,” Nano Energy 12 (2015): 141–151.
[140]

R. Deepa and K. A. Vijayalakhmi, “Eco-Friendly High Microporosity Low Temperature Plasma Exposed Activated Carbon From Coconut Shell for Nano Hybrid Supercapacitors,” Physica Scripta 99, no. 12 (2024): 125601.
[141]

C. Leng, K. Sun, J. Li, and J. Jiang, “From Dead Pine Needles to O, N Codoped Activated Carbons by a One-Step Carbonization for High Rate Performance Supercapacitors,” ACS Sustainable Chemistry & Engineering 5, no. 11 (2017): 10474–10482.
[142]

S. R. A. Sasono, M. F. Rois, W. Widiyastuti, T. Nurtono, and H. Setyawan, “Nanofiber-Enrich Dispersed Activated Carbon Derived From Coconut Shell for Supercapacitor Material,” Results in Engineering 18 (2023): 101070.
[143]

R. Nandi, M. K. Jha, S. K. Guchhait, D. Sutradhar, and S. Yadav, “Impact of KOH Activation on Rice Husk Derived Porous Activated Carbon for Carbon Capture at Flue Gas Alike Temperatures With High CO2/N2 Selectivity,” ACS Omega 8, no. 5 (2023): 4802–4812.
[144]

P. Sivasubramanian, M. Kumar, and J.-H. Chang, “A Novel Technique of Dual Modified Acid-Washed Layered Double Hydroxides-Biochar for Adsorption and as Potential Catalysts for Electrochemical Applications,” Bioresource Technology Reports 28 (2024): 101956.
[145]

D. Priyadharshini and S. Vivekanandhan, “Gracilaria Edulis Seaweed Derived Nitrogen, Oxygen, and Sulfur Self-Doped Biocarbon Materials for Supercapacitor Applications: An Investigation on the Impact of Acid Washing and Activation,” Energy Storage 6, no. 1 (2023): e526.
[146]

C. Li, L. J. Yan, M. J. Wang, J. Kong, W. Bao, and L. Chang, “Sustainable Utilization of Waste Biomass (Benincasa Hispida): Synthesis of N, O-Doped Foamy Porous Carbon With High Capacitive Properties by One-Step Oxidation-Activation,” Journal of Energy Storage 107 (2025): 114887.
[147]

A. A. Mohammed, J. K. Das, A. Hota, S. Sahoo, K. I. Ayinla, and B. Tripathy, “Mixed Biomass-Derived Multi-Heteroatom Doped Carbon-Decorated Mn3O4 for a High-Performance Asymmetric All Solid-State Supercapacitor,” Materials Research Bulletin 177 (2024): 112849.
[148]

K. Kumar, U. Tyagi, S. Sirohi, et al., “A Critical Review on Nanostructure-Doped Carbonized Biomass: A New Era in Sustainable Supercapacitor Technology,” Fuel 381 (2025): 133707.
[149]

W. Li, W. H. Zhang, Y. Xu, et al., “Heteroatom-Doped Lignin Derived Carbon Materials With Improved Electrochemical Performance for Advanced Supercapacitors,” Chemical Engineering Journal 497 (2024): 154829.
[150]

M. Zimik, S. Sarmah, B. K. Kakati, D. Deka, and R. Thangavel, “Pyrolytic Conversion of Mesua Ferrea Testa to Nitrogen-Doped Porous Carbon for Supercapacitor Applications,” Materials Research Bulletin 180 (2024): 113017.
[151]

Y. Wang, D. Wang, Z. Li, et al., “Preparation of Boron/Sulfur-Codoped Porous Carbon Derived From Biological Wastes and Its Application in a Supercapacitor,” Nanomaterials 12, no. 7 (2022): 1182.
[152]

D. Chernysheva, M. Konstantinov, E. Sidash, et al., “Fomes Fomentarius as a Bio-Template for Heteroatom-Doped Carbon Fibers for Symmetrical Supercapacitors,” Symmetry-Basel 15, no. 4 (2023): 846.
[153]

X. He, W. Li, Y. Xia, et al., “Pivotal Factors of Wood-Derived Electrode for Supercapacitor: Component Striping, Specific Surface Area and Functional Group at Surface,” Carbon 210 (2023): 118090.
[154]

J. Y. Zhuang, G. Li, M. H. Wang, and L. Jia, “Biomass-Derived Carbon Quantum Dots-Induced Self-Assembly of 3D Networks of Nickel-Cobalt Double Hydroxide Nanorods as High-Performance Electrode Materials for Supercapacitors,” ChemElectroChem 9, no. 10 (2022): e202200296.
[155]

Y. H. Bao, H. Xu, Y. Q. Zhu, P. Chen, Y. Zhang, and Y. Chen, “2,6-Diaminoanthraquinone Anchored on Functionalized Biomass Porous Carbon Boosts Electrochemical Stability for Metal-Free Redox Supercapacitor Electrode,” Electrochimica Acta 437 (2023): 141533.
[156]

Y. L. Wang, Y. L. Jin, W. H. Tian, et al., “Hydrangea-Like NiMn Layered Double Hydroxide Grown on Biomass-Derived Porous Carbon as a High-Performance Supercapacitor Electrode,” Industrial Crops and Products 222 (2024): 120035.
[157]

H. W. Guo, A. T. Zhang, H. C. Fu, et al., “In Situ Generation of CeCoSx Bimetallic Sulfide Derived From ‘Egg-Box’ Seaweed Biomass on S/N Co-Doped Graphene Aerogels for Flexible All Solid-State Supercapacitors,” Chemical Engineering Journal 453 (2023): 139633.
[158]

D. Gogoi, P. Makkar, M. R. Das, and N. N. Ghosh, “CoFe2O4 Nanoparticle Decorated Hierarchical Biomass Derived Porous Carbon Based Nanocomposites for High-Performance All-Solid-State Flexible Asymmetric Supercapacitor Devices,” ACS Applied Electronic Materials 4, no. 2 (2022): 795–806.
[159]

J. L. Yi, F. X. Song, L. J. Zhou, Q. Chen, L. Pan, and M. Yang, “Co1-XS/Co3S4@N,S-Co-Doped Agaric-Derived Porous Carbon Composites for High-Performance Supercapacitors,” Electrochimica Acta 426 (2022): 140825.
[160]

N. S. George, G. Singh, R. Bahadur, et al., “Recent Advances in Functionalized Biomass-Derived Porous Carbons and Their Composites for Hybrid Ion Capacitors,” Advanced Science 11, no. 35 (2024): 2406235.
[161]

H. W. Park, H. J. Ahn, and K. C. Roh, “Recent Advances in Preparation and Supercapacitor Applications of Lignin-Derived Porous Carbon: A Review,” Journal of Electrochemical Science and Technology 15, no. 1 (2024): 111–131.
[162]

H. Yaquin, G. R. Dheep, and Y. K. Verma, “Fabrication and Development of a Biomass-Based Supercapacitor With Enhanced Energy Storage Characteristics,” ECS Journal of Solid State Science and Technology 13, no. 2 (2024): 021003.
[163]

P. Saha, M. Z. Islam, S. S. Shah, et al., “Harnessing the Power of Marine Biomass-Derived Carbon for Electrochemical Energy Storage,” Battery Energy (2024): e20240055.
[164]

C. F. Xue, T. Wu, W. Zhao, et al., “High-Rate Electrochemical Supercapacitor With Attractive Energy Density Assembling From Infused-Undaria-Pinnatifida-Based Activated Carbon,” Journal of Energy Storage 80 (2024): 110362.
[165]

C. A. Yuan, H. Xu, S. A. El-khodary, et al., “Recent Advances and Challenges in Biomass-Derived Carbon Materials for Supercapacitors: A Review,” Fuel 362 (2024): 130795.
[166]

R. Kwarciany, M. Fiedur, and B. Saletnik, “Opportunities and Threats for Supercapacitor Technology Based on Biochar-A Review,” Energies 17, no. 18 (2024): 4617.
[167]

W. Zhong, W. T. Su, P. H. Li, K. Li, W. Wu, and B. Jiang, “Preparation and Research Progress of Lignin-Based Supercapacitor Electrode Materials,” International Journal of Biological Macromolecules 259 (2024): 128942.
[168]

C. H. Zhao, X. Z. Tong, Y. R. Yang, et al., “Loofah Sponge-Derived 3D Flexible Porous Carbon Electrode for High Performance Supercapacitor,” Journal of Energy Storage 78 (2024): 110295.
[169]

Q. J. Tong, Z. H. Zhang, Q. T. Luo, et al., “Regulating and Unraveling Electrochemical Behavior of Hierarchically-Densifying Mesoporous Apocynum Carbon for High Performance Supercapacitor,” Batteries & Supercaps (2024): e202400450.
[170]

G. Y. Xia, Z. L. Liu, J. S. He, et al., “Modulating Three-Dimensional Porous Carbon From Paper Mulberry Juice by a Hydrothermal Process for a Supercapacitor With Excellent Performance,” Renewable Energy 227 (2024): 120478.
[171]

Y. Y. Wang, X. S. Dong, Y. J. Xia, et al., “N/O Co-Doped Litchi Peel Derived Porous Carbon Materials for Supercapacitors,” Journal of Physics and Chemistry of Solids 198 (2025): 112472.
[172]

L. C. Wang, R. Y. Fu, X. Y. Qi, et al., “Deashing Strategy on Biomass Carbon for Achieving High-Performance Full-Supercapacitor Electrodes,” ACS Applied Materials & Interfaces 16, no. 39 (2024): 52663–52673.
[173]

E. Taer, A. Apriwandi, W. M. Nasution, A. Fudholi, N. Chitraningrum, and R. Taslim, “Mangosteen Peel Waste Derived Sulfur-Oxygen Self-Dual-Doped Hierarchical Porous Carbon Nanofiber for Ultrahigh Energy of Solid-State Supercapacitor,” Bioresource Technology Reports 28 (2024): 102004.
[174]

E. Taer, N. Nursyafni, W. Febriani, et al., “Self-Single-Doped Hierarchical Porous Carbon Nanofiber Derived Alpinia galanga Stem-Based for Boosted Supercapacitor Performance,” Materials Letters 360 (2024): 135954.
[175]

R. Sun, Y. Chen, X. Gao, et al., “Sodium Lignosulfonate-Derived Hierarchical Porous Carbon Electrode Materials for Supercapacitor Applications,” Journal of Energy Storage 91 (2024): 112025.
[176]

S. S. Lu, W. S. Yang, M. Zhou, et al., “Nitrogen- and Oxygen-Doped Carbon With Abundant Micropores Derived From Biomass Waste for All-Solid-State Flexible Supercapacitors,” Journal of Colloid and Interface Science 610 (2022): 1088–1099.
[177]

N. S. Priya, J. B. Mathangi, K. Gopalram, and M. Helen Kalavathy, “Morphological and Electrochemical Properties of Citrullus Lanatus-Derived Activated Carbon for Supercapacitor Applications,” Bulletin of Materials Science 46, no. 2 (2023): 110.
[178]

L. H. Zheng, M. H. Chen, S.-X. Liang, and Q. F. , “Oxygen-Rich Hierarchical Porous Carbon Derived From Biomass Waste-Kapok Flower for Supercapacitor Electrode,” Diamond and Related Materials 113 (2021): 108267.
[179]

J. S. Feng, X. T. Zhang, Q. F. Lu, E. Guo, and M. Wei, “Fabrication of a High-Performance Hybrid Supercapacitor Based on NiCo2S4 Nanoneedles/Biomass Porous Carbon,” Energy & Fuels 36, no. 10 (2022): 5424–5432.
[180]

R. J. Wesley, S. Vasanth, A. Durairaj, et al., “Nickel-Molybdenum Bimetallic Sulfide Decorated Biomass Derived Carbon Support for High Performance Asymmetric Supercapacitor Application,” Journal of Energy Storage 91 (2024): 112092.
[181]

X. T. Wang, Z. Y. Xiao, W. S. Niu, et al., “Co2P-Co3(Po4)2 Nanoparticles Immobilized on Kelp-Derived 3D Honeycomb-Like P-Doped Porous Carbon as Cathode Electrode for High-Performance Asymmetrical Supercapacitor,” Colloids and Surfaces A: Physicochemical and Engineering Aspects 655 (2022): 130192.
[182]

S. S. Gunasekaran, A. Gopalakrishnan, R. Subashchandrabose, and S. Badhulika, “Phytogenic Generation of Nio Nanoparticles as Green-Electrode Material for High Performance Asymmetric Supercapacitor Applications,” Journal of Energy Storage 37 (2021): 102412.
[183]

B. Yuan, Z. L. Su, K. X. Chen, et al., “Design of NiCo2O4 Nanoparticles In-Situ Grown on Lignin-Derived Porous Carbon and MWCNTS Composites for Supercapacitors,” Diamond and Related Materials 136 (2023): 110079.
[184]

R. Y. Zou, B. L. Wang, L. Zhu, et al., “Biomass Derived Porous Carbon Supported Nano-Co3O4 Composite for High-Performance Supercapacitors,” Diamond and Related Materials 126 (2022): 109060.
[185]

Y. P. Zhang, H. L. Wei, H. Kimura, et al., “Facile Synthesis, Microstructure and Electrochemical Performance of Peanut Shell Derived Porous Activated Carbon/Co3O4 Composite for Hybrid Supercapacitors,” Ceramics International 48, no. 23 (2022): 34576–34583.
[186]

S. Dhinesh, M. Priyadharshini, T. Pazhanivel, and R. Gobi, “Biomass-Derived N, S Self-Doped Activated Carbon Embedded MnO2 as Cathode for Supercapacitor,” Materials Technology 37, no. 11 (2022): 1837–1845.
[187]

R. Wang, X. Y. Li, Z. G. Nie, Y. Wang, Y. Zhao, and H. Wang, “NiCo2O4 Hexagonal Nanoplates/Cornstalk-Derived Porous Carbon Composites for High-Performance Supercapacitor Electrodes,” Energy & Fuels 36, no. 21 (2022): 13256–13265.
[188]

M. Ojha, S. Naskar, B. Kaur, A. Kolay, and M. Deepa, “Lithiated Tin Di-Sulfide Micro-Flowers With Expanded Interlayer Spaces Coupled With Bakelite-Carbon for an Enhanced Performance Supercapacitor,” Journal of Energy Storage 44 (2021): 103463.
[189]

S. B. N. De, C. K. Maity, M. J. Kim, and G. C. Nayak, “Tin(IV) Selenide Anchored-Biowaste Derived Porous Carbon-Ti3C2Tx (MXene) Nanohybrid: An Ionic Electrolyte Enhanced High Performing Flexible Supercapacitor Electrode,” Electrochimica Acta 463 (2023): 142811.
[190]

C. Poochai, A. Srikhaow, J. Lohitkarn, et al., “Waste Coffee Grounds Derived Nanoporous Carbon Incorporated With Carbon Nanotubes Composites for Electrochemical Double-Layer Capacitors in Organic Electrolyte,” Journal of Energy Storage 43 (2021): 103169.
[191]

L. S. Wei, W. J. Deng, S. S. Li, Z. Wu, J. Cai, and J. Luo, “Sandwich-Like Chitosan Porous Carbon Spheres/MXene Composite With High Specific Capacitance and Rate Performance for Supercapacitors,” Journal of Bioresources and Bioproducts 7, no. 1 (2022): 63–72.
[192]

G. G. Duan, S. Y. Zeng, H. T. Jin, et al., “Bamboo-Templated MOF-67-Derived Carbon: A High-Performance Electrode for Supercapacitors,” Industrial Crops and Products 222 (2024): 119616.
[193]

X. X. Ma, Y. F. Bai, S. L. Chen, et al., “A Composite of Pineapple Leaf-Derived Porous Carbon Integrated With ZnCo-MOF for High-Performance Supercapacitors,” Physical Chemistry Chemical Physics 26, no. 45 (2024): 28746–28756.
[194]

S. P. Yao, L. Chen, Y. M. Guo, S. Zong, H. Zhang, and J. Feng, “Hydrangea-Like MnO2@Sulfur-Doped Porous Carbon Spheres With High Packing Density for High-Performance Supercapacitor,” Journal of Electroanalytical Chemistry 976 (2025): 118802.
[195]

K. K. R. Reddygunta and B. D. Kumar, “Biomass Activated Carbon Composites and Their Potential in Supercapacitor Applications: Current Trends and Future Perspectives,” Energy & Fuels 38, no. 12 (2024): 10560–10588.
[196]

Suman, G. Rani, R. Ahlawat, and H. Kumar, “Green Source-Based Carbon Quantum Dots, Composites, and Key Factors for High-Performance of Supercapacitors,” Journal of Power Sources 617 (2024): 235170.
[197]

S. Y. Cheng, X. W. Wang, K. Du, et al., “Hierarchical Lotus-Seedpod-Derived Porous Activated Carbon Encapsulated With NiCo2S4 for a High-Performance All-Solid-State Asymmetric Supercapacitor,” Molecules 28, no. 13 (2023): 5020.
[198]

X. Y. Du, C. X. Hou, H. Kimura, et al., “Energy- and Cost-Efficient CaCo3-Assisted Nanoarchitectonics of Recycled Wheat Flour-Derived Carbon Matrix Decorated With MnO2 Nanoparticles for High-Performance Supercapacitor,” Journal of Energy Storage 72 (2023): 108355.
[199]

Y. H. Cui, Q. S. Shi, Z. Liu, et al., “MXene/Biomass/Chitosan Carbon Aerogel (MBC) With Shared Cathode and Anode for the Construction of High-Efficiency Asymmetric Supercapacitor,” Chemical Engineering Journal 472 (2023): 144701.
[200]

W. Chen, Z. Li, K. Yang, et al., “Low-Temperature Carbonized MXene/Protein-Based Eggshell Membrane Composite as Free-Standing Electrode for Flexible Supercapacitors,” International Journal of Biological Macromolecules 226 (2023): 588–596.
[201]

L. Sun, Y. Dong, H. Y. Li, et al., “Research Progress and Challenges of Carbon/MXene Composites for Supercapacitors,” Batteries-Basel 10, no. 11 (2024): 395.
[202]

L. Sun, Q. Fu, and C. Pan, “Hierarchical Porous ‘Skin/Skeleton’-Like MXene/Biomass Derived Carbon Fibers Heterostructure for Self-Supporting, Flexible All Solid-State Supercapacitors,” Journal of Hazardous Materials 410 (2021): 124565.
[203]

M. Hu, T. Hu, R. Cheng, et al., “MXene-Coated Silk-Derived Carbon Cloth Toward Flexible Electrode for Supercapacitor Application,” Journal of Energy Chemistry 27, no. 1 (2018): 161–166.
[204]

Y. L. Jin, J. H. Geng, Y. L. Wang, et al., “Flexible All-Solid-State Asymmetric Supercapacitor Based on Ti3C2Tx MXene/Graphene/Carbon Nanotubes,” Surfaces and Interfaces 53 (2024): 104999.
[205]

N. K. P. Siddu, S. M. Jeong, and C. S. Rout, “MXene-Carbon Based Hybrid Materials for Supercapacitor Applications,” Energy Advances 3, no. 2 (2024): 341–365.
[206]

S. K. Kim, S. A. Kim, Y. S. Han, and K. H. Jung, “Supercapacitor Performance of MXene-Coated Carbon Nanofiber Electrodes,” C-Journal of Carbon Research 10, no. 2 (2024): 32.
[207]

Q. W. Fan, C. Y. Song, Y. C. Zhang, G. Ren, Y. Sun, and P. Fu, “Biomass-Based Porous Carbon With Surface Grown MXenes for High-Performance Electromagnetic Absorption and Supercapacitor Validated From Structural and Charge Changes,” Journal of Materials Science 58, no. 44 (2023): 17045–17065.
[208]

O. P. Nanda, A. G. Prince, L. Durai, and S. Badhulika, “Nickel MXene Nanosheet and Heteroatom Self-Doped Porous Carbon-Based Asymmetric Supercapacitors With Ultrahigh Energy Density,” Energy & Fuels 37, no. 6 (2023): 4701–4710.
[209]

W. H. Peng, N. N. Song, Z. L. Su, et al., “Two-Dimensional MoS2/Mn-MOF/Multi-Walled Carbon Nanotubes Composite Material for High-Performance Supercapacitors,” Microchemical Journal 179 (2022): 107506.
[210]

K. Zhao, Z. H. Wang, X. L. Sun, et al., “Metal-Organic Framework Derived Nickel-Cobalt Layered Double Hydroxide Nanosheets Cleverly Constructed on Interconnected Nano-Porous Carbon for High-Performance Supercapacitors,” Journal of Energy Storage 60 (2023): 106559.
[211]

A. Jayakumar, R. P. Antony, J. Zhao, and J. M. Lee, “MOF-Derived Nickel and Cobalt Metal Nanoparticles in a N-Doped Coral Shaped Carbon Matrix of Coconut Leaf Sheath Origin for High Performance Supercapacitors and OER Catalysis,” Electrochimica Acta 265 (2018): 336–347.
[212]

C. Yan, J. Wei, J. Guan, Z. Shao, and S. Lv, “Highly Foldable and Free-Standing Supercapacitor Based on Hierarchical and Hollow MOF-Anchored Cellulose Acetate Carbon Nanofibers,” Carbon 213 (2023): 118187.
[213]

M. Wang, J. Zhang, X. Yi, B. Liu, X. Zhao, and X. Liu, “High-Performance Asymmetric Supercapacitor Made of NiMoO4 Nanorods@Co3O4 on a Cellulose-Based Carbon Aerogel,” Beilstein Journal of Nanotechnology 11 (2020): 240–251.
[214]

W. Ye, J. Cai, F. Yu, X. Li, and X. Wang, “Nitrogen-Doped Bagasse Carbon Spheres/Graphene Composite for High-Performance Supercapacitors,” Biomass and Bioenergy 145 (2021): 105949.
[215]

R. Chen, X. Li, Q. Huang, H. Ling, Y. Yang, and X. Wang, “Self-Assembled Porous Biomass Carbon/RGO/Nanocellulose Hybrid Aerogels for Self-Supporting Supercapacitor Electrodes,” Chemical Engineering Journal 412 (2021): 128755.
[216]

L. Guardia, L. Suarez, N. Querejeta, et al., “Biomass Waste-Carbon/Reduced Graphene Oxide Composite Electrodes for Enhanced Supercapacitors,” Electrochimica Acta 298 (2019): 910–917.
[217]

H. Chen, L. Zhang, H. Wang, D. Sui, F. Meng, and W. Qi, “Synergetic Modulation of Graphene Oxide and Metal Oxide Particles for Exploring Integrated Capacitance of Milk Colloid-Derived Carbon,” Colloids and Surfaces A: Physicochemical and Engineering Aspects 608 (2021): 125599.
[218]

L. Jin, K. Wei, Y. Xia, et al., “Tree Leaves-Derived Three-Dimensional Porous Networks as Separators for Graphene-Based Supercapacitors,” Materials Today Energy 14 (2019): 100348.
[219]

G. Oskueyan, M. M. Lakouraj, and M. Mahyari, “Fabrication of Polyaniline-Carrot Derived Carbon Dots/Polypyrrole-Graphene Nanocomposite for Wide Potential Window Supercapacitor,” Carbon Letters 31, no. 2 (2021): 269–276.
[220]

R. Lima, G. S. dos Reis, U. Lassi, et al., “Sustainable Supercapacitors Based on Polypyrrole-Doped Activated Biochar From Wood Waste Electrodes,” C-Journal of Carbon Research 9, no. 2 (2023): 59.
[221]

C. Lv, X. Ma, R. Guo, et al., “Polypyrrole-Decorated Hierarchical Carbon Aerogel From Liquefied Wood Enabling High Energy Density and Capacitance Supercapacitor,” Energy 270 (2023): 126830.
[222]

P. Dubey, V. Shrivastav, M. Jain, K. K. Pant, P. H. Maheshwari, and S. Sundriyal, “Facile Synthesis of Pineapple Waste-Derived Carbon and Polyaniline Composite for High-Energy-Density Asymmetric Supercapacitors,” Energy & Fuels 37, no. 12 (2023): 8659–8671.
[223]

K. Thongkam, N. Chaiyut, M. Panapoy, and B. Ksapabutr, “Biomass-Based Nitrogen-Doped Carbon/Polyaniline Composite as Electrode Material for Supercapacitor Devices,” Journal of Metals, Materials and Minerals 33, no. 3 (2023): 1675.
[224]

N. Sheng, S. Chen, J. Yao, et al., “Polypyrrole@TEMPO-Oxidized Bacterial Cellulose/Reduced Graphene Oxide Macrofibers for Flexible All-Solid-State Supercapacitors,” Chemical Engineering Journal 368 (2019): 1022–1032.
[225]

P. Panith, P. Butnoi, and V. Intasanta, “The Hybrid Structure of Nanoflower-Like CoxMnyNizO4 Nanoparticles Embedded Biomass-Lignin Carbon Nanofibers as Free-Standing and Binder-Free Electrodes for High Performance Supercapacitors,” Journal of Alloys and Compounds 918 (2022): 165659.
[226]

X. Wang, J. Chu, H. J. Yan, and H. Zhang, “Synthesis and Characterization of MnO2/Eggplant Carbon Composite for Enhanced Supercapacitors,” Heliyon 8, no. 9 (2022): e10631.
[227]

R. Y. Zou, L. Zhu, L. J. Yan, B. Shao, H. Cheng, and W. Sun, “Co3O4 Anchored on Meshy Biomass Carbon Derived From Kelp for High-Performance Ultracapacitor Electrode,” Materials Chemistry and Physics 266 (2021): 124556.
[228]

B. Lesbayev, M. Auyelkhankyzy, G. Ustayeva, et al., “Modification of Biomass-Derived Nanoporous Carbon With Nickel Oxide Nanoparticles for Supercapacitor Application,” Journal of Composites Science 7, no. 1 (2023): 20.
[229]

H. Wang, H. Chen, X. Hou, et al., “MnO Decorated Biomass Derived Carbon Based on Hyperaccumulative Characteristics as Advanced Electrode Materials for High-Performance Supercapacitors,” Diamond and Related Materials 136 (2023): 109888.
[230]

T. Wen, R. Li, P. Xu, et al., “Scalable Synthesis of Ta1.1O1.05/Biomass Carbon Composite With Multiple Structure Engineering by Boron-Doped Graphene Quantum Dot for High-Energy Supercapacitor,” Applied Surface Science 615 (2023): 156387.
[231]

T. Yu, F. Wang, X. Zhang, et al., “Typha Orientalis Leaves Derived P-Doped Hierarchical Porous Carbon Electrode and Carbon/MnO2 Composite Electrode for High-Performance Asymmetric Supercapacitor,” Diamond and Related Materials 116 (2021): 108450.
[232]

Y. He, J. Ren, X. Lin, et al., “Filling and Coating Nickel Foam With N-Doped Biomass-Char to Anchor Ni0.33Co0.67MoO4 Nanosheet Arrays for Enhanced Supercapacitive Performance,” Ionics 29, no. 7 (2023): 2887–2898.
[233]

H. X. Hu, K. D. Li, X. S. Li, L. Wang, X. Yang, and Q. Zhang, “Facile Fabrication of NiCo-LDH on Activated Rice Husk Carbon for High-Performance All-Solid-State Asymmetric Supercapacitors,” New Journal of Chemistry 47, no. 29 (2023): 14030–14038.
[234]

K. Zhao, X. L. Sun, Z. H. Wang, C. Huang, D. Li, and J. Liu, “Sheet-Like Nico-Layered Double Hydroxide Anchored on N Self-Doped Hierarchical Porous Carbon Aerogel From Chitosan for High-Performance Supercapacitors,” Journal of Alloys and Compounds 921 (2022): 166036.
[235]

H. N. Chen, X. P. Lei, T. Yu, J. Liu, and K. Fan, “Self-Grown Nickel Hydroxide Nanosheets on 3D Hierarchical Porous Turtle Shell-Derived Activated Carbon for High-Performance Supercapacitors,” Fuel 316 (2022): 123357.
[236]

F. Yang, J. Chu, Y. Cheng, J. Gong, X. Wang, and S. Xiong, “Hydrothermal Synthesis of Nico-Layered Double Hydroxide Nanosheets Decorated on Biomass Carbon Skeleton for High Performance Supercapacitor,” Chemical Research in Chinese Universities 37, no. 3 (2021): 772–777.
[237]

K. L. Fang, M. F. Chen, J. Z. Chen, Q. Tian, and C. P. Wong, “Cotton Stalk-Derived Carbon Fiber@Ni-Al Layered Double Hydroxide Nanosheets With Improved Performances for Supercapacitors,” Applied Surface Science 475 (2019): 372–379.
[238]

K. Q. Qu, M. H. Chen, W. C. Wang, et al., “Biomass-Derived Carbon Dots Regulating Nickel Cobalt Layered Double Hydroxide From 2D Nanosheets to 3D Flower-Like Spheres as Electrodes for Enhanced Asymmetric Supercapacitors,” Journal of Colloid and Interface Science 616 (2022): 584–594.
[239]

M. Sakthivel, S. Ramki, S. M. Chen, and K. C. Ho, “Defect Rich Se–CoWS2 as Anode and Banana Flower Skin-Derived Activated Carbon Channels With Interconnected Porous Structure as Cathode Materials for Asymmetric Supercapacitor Application,” Energy 257 (2022): 124758.
[240]

M. Xu, A. Wang, Y. Xiang, and J. Niu, “Biomass-Based Porous Carbon/Graphene Self-Assembled Composite Aerogels for High-Rate Performance Supercapacitor,” Journal of Cleaner Production 315 (2021): 128110.
[241]

J. E. Madhusree, P. R. Chandewar, D. Shee, and S. Sankar Mal, “Phosphomolybdic Acid Embedded Into Biomass-Derived Biochar Carbon Electrode for Supercapacitor Applications,” Journal of Electroanalytical Chemistry 936 (2023): 117354.
[242]

R. J. Wesley, S. Sowmya, A. Durairaj, R. Justinabraham, V. Vijaikanth, and S. Vasanthkumar, “Eggshell Waste-Derived Carbon Composite With Calcium Bismuth Oxide for Energy Storage Application,” Journal of Electronic Materials 52, no. 10 (2023): 6503–6513.
[243]

H. M. Zhou, Y. B. Zhan, F. Q. Guo, et al., “Synthesis of Biomass-Derived Carbon Aerogel/MnOx Composite as Electrode Material for High-Performance Supercapacitors,” Electrochimica Acta 390 (2021): 138817.
[244]

Z. J. Cao, R. Y. Li, P. W. Xu, and H. Zhu, “Highly Dispersed RuO2-Biomass Carbon Composite Made by Immobilization of Ruthenium and Dissolution of Coconut Meat With Octyl Ammonium Salicylate Ionic Liquid for High Performance Flexible Supercapacitor,” Journal of Colloid and Interface Science 606 (2022): 424–433.
[245]

R. Y. Wang, M. F. Zhang, H. Xu, et al., “One-Step Synthesis of Popcorn-Carbon/Co3O4 Composites as High-Performance Supercapacitor Electrodes,” Crystals 12, no. 1 (2022): 76.
[246]

W. P. Li, X. K. Xu, Y. Q. Yang, et al., “Biomass Absorption of Nickel Salt Derived Carbon Wrapped NiS/Ni3S4 Nanocomposite as Efficient Electrode for Supercapacitors,” Journal of Alloys and Compounds 934 (2023): 167838.
[247]

Q. Tang, X. Y. Chen, D. L. Zhou, and C. Liu, “Biomass-Derived Hierarchical Porous Carbon/Silicon Carbide Composite for Electrochemical Supercapacitor,” Colloids and Surfaces A: Physicochemical and Engineering Aspects 620 (2021): 126567.
[248]

E. Yi, X. Shen, X. Chen, et al., “Preparation of Biomass Composite Activated Carbon Based Supercapacitor Materials and Their Application in Energy Storage Devices,” Chemical Engineering Science 282 (2023): 119193.
[249]

L. G. Yue, L. Chen, X. Liu, D. Lu, W. Zhou, and Y. Li, “Honeycomb-Like Biomass Carbon With Planted CoNi3 Alloys to Form Hierarchical Composites for High-Performance Supercapacitors,” Journal of Colloid and Interface Science 608 (2022): 2602–2612.
[250]

M. Ma, W. Cai, Y. Chen, Y. Li, F. Tan, and J. Zhou, “Flower-Like NiMn-Layered Double Hydroxide Microspheres Coated on Biomass-Derived 3D Honeycomb Porous Carbon for High-Energy Hybrid Supercapacitors,” Industrial Crops and Products 166 (2021): 113472.
[251]

S. Yu, Y. Ye, M. Yang, et al., “Ammonium Folate-Reinforced Self-Assembly of Gelatin Into N/B/O-Enriched Hierarchical Porous Carbons With Loosely Layered Structure for Anti-Freezing Flexible Supercapacitors,” Small 20, no. 8 (2024): e2306267.
[252]

S. Zhang, X. Wang, T. Lv, et al., “The Secret of the Magic Gourd(I): Biomass From Various Organizations of Ourds as a Sustainable Source for High-Performance Supercapacitors,” Science China Chemistry (2024): 1–16.
[253]

S. Zhai, K. Li, C. Li, et al., “Lignin-Derived N,S-Codoped Hierarchical Porous Carbons With High Mesoporous Rate for Sustainable Supercapacitive Energy Storage,” Journal of Energy Storage 85 (2024): 111036.
[254]

Z. Huang, J. Chen, H. Chen, et al., “Tailoring Moldy-Mulberry-Derived Carbons for Ionic Liquid-Based Supercapacitors With Ultrahigh Energy Density,” Diamond and Related Materials 144 (2024): 110994.
[255]

H. Zhang, L. Lin, W. Kong, et al., “Hierarchically Bread-Derived Carbon Foam Decorated With Defect Engineering in Reduced Graphene Oxide/Carbon Particle Nanocomposites as Electrode Materials for Solid-State Supercapacitors,” Journal of Energy Storage 68 (2023): 107616.
[256]

G. Zhu, L. Ma, H. Lin, et al., “High-Performance Li-Ion Capacitor Based on Black-TiO2-X/Graphene Aerogel Anode and Biomass-Derived Microporous Carbon Cathode,” Nano Research 12, no. 7 (2019): 1713–1719.
[257]

J. Hu, C. Zhao, Y. Si, et al., “Chitosan-Derived Large Surface Area Porous Carbon via Microphase Separation Engineering of Pore-Regulation and Nitrogen-Doping Coupling for High-Performance Supercapacitors,” Renewable Energy 228 (2024): 120598.
[258]

S. Zhong, L. Dai, H. Xu, X. C. Yang, X. Zheng, and S. Wang, “Highly Porous Carbon With Selective Transformation of Nitrogen Groups Boosts the Capacitive Performance Through Boric Acid Template Assisted Strategy,” Journal of Energy Storage 97 (2024): 112867.
[259]

S. Lu, Q. Xiao, W. Yang, et al., “Multi-Heteroatom-Doped Porous Carbon With High Surface Adsorption Energy of Potassium Derived From Biomass Waste for High-Performance Supercapacitors,” International Journal of Biological Macromolecules 258, no. Pt. 1 (2024): 128794.
[260]

R. Chen, H. Tang, P. He, et al., “Interface Engineering of Biomass-Derived Carbon Used as Ultrahigh-Energy-Density and Practical Mass-Loading Supercapacitor Electrodes,” Advanced Functional Materials 33, no. 8 (2022): 2212078.
[261]

W. Fan, J. Ding, J. Ding, et al., “Identifying Heteroatomic and Defective Sites in Carbon With Dual-Ion Adsorption Capability for High Energy and Power Zinc Ion Capacitor,” Nano-Micro Letters 13, no. 1 (2021): 59.

RIGHTS & PERMISSIONS

2025 The Author(s). EcoEnergy published by John Wiley & Sons Australia, Ltd on behalf of China Chemical Safety Association.

AI Summary AI Mindmap
PDF

33

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/