Activated carbon prepared by hydrothermal pretreatment-assisted chemical activation of date seeds for supercapacitor application
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O. Bacha | D. Zerrouki | A. Henni | N. Harfouche | H. Belkhalfa | B. Said | Y. Rahmani | H. Kheniche | H. Belkhalfa
[1] Syed Shaheen Shah,et al. Preparation and electrochemical performance of Convolvulus arvensis-derived activated carbon for symmetric supercapacitors , 2023, Materials Science and Engineering: B.
[2] Lan Xu,et al. One-dimensional nanostructured electrode materials based on electrospinning technology for supercapacitors , 2023, Diamond and Related Materials.
[3] Priya S. Gadekar,et al. Advanced polymer-based materials and mesoscale models to enhance the performance of multifunctional supercapacitors , 2023, Journal of Energy Storage.
[4] Qinfeng Rong,et al. Stretchable all-in-one supercapacitor enabled by poly(ethylene glycol)-based hydrogel electrolyte with low-temperature tolerance , 2023, Polymer.
[5] Vishal Shrivastav,et al. Effect of nitrogen and sulphur co-doping on the surface and diffusion characteristics of date seed-derived porous carbon for asymmetric supercapacitors , 2023, Journal of Energy Storage.
[6] E. Taer,et al. Sustainable development of biomass-derived activated carbon through chemical and physical activations and its effect on the physicochemical and electrochemical activity , 2023, Energy Sources, Part A: Recovery, Utilization, and Environmental Effects.
[7] J. Fito,et al. Adsorption of Congo Red from Textile Wastewater Using Activated Carbon Developed from Corn Cobs: The Studies of Isotherms and Kinetics , 2023, Chemistry Africa.
[8] Shalendra Kumar,et al. Fabrication of a Biomass-Derived Activated Carbon-Based Anode for High-Performance Li-Ion Batteries , 2023, Micromachines.
[9] Hong Wang,et al. Biomass-derived porous activated carbon for ultra-high performance supercapacitor applications and high flux removal of pollutants from water , 2023, Ceramics International.
[10] R. Farma,et al. Hierarchical-nanofiber structure of biomass-derived carbon framework with direct CO2 activation for symmetrical supercapacitor electrodes , 2023, Journal of Materials Science: Materials in Electronics.
[11] Guojie Zhang,et al. Synthesis and characterization of magnetic K2CO3-activated carbon produced from bamboo shoot for the adsorption of Rhodamine b and CO2 capture , 2023, Fuel.
[12] Sasanka Deka. Nanostructured mixed transition metal oxide spinels for supercapacitor applications. , 2022, Dalton transactions.
[13] A. M. Abed,et al. Graphene-Based Important Carbon Structures and Nanomaterials for Energy Storage Applications as Chemical Capacitors and Supercapacitor Electrodes: a Review , 2022, BioNanoScience.
[14] G. Sonnemann,et al. Life Cycle Assessment of Supercapacitor Electrodes Based on Activated Carbon from Coconut Shells , 2022, ACS Sustainable Chemistry & Engineering.
[15] Hao Li,et al. A Novel Embedded All-Solid-State Composite Structural Supercapacitor , 2022, SSRN Electronic Journal.
[16] S. Uchida,et al. Comparative performance analysis of photo-supercapacitor based on silicon, dye-sensitized and perovskite solar cells: Towards indoor applications , 2022, Solar Energy Materials and Solar Cells.
[17] L. Goveas,et al. Adsorptive removal of tetracycline from aqueous solutions using magnetic Fe2O3 / activated carbon prepared from Cynometra ramiflora fruit waste. , 2022, Chemosphere.
[18] Emre Biçer,et al. Double-Decker Lutetium and Europium Phthalocyanine Composites with Reduced Graphene Oxide as Supercapacitor Electrode Materials , 2022, Journal of Organometallic Chemistry.
[19] T. Hansu,et al. Production of a novel supercapacitor electrode material from Rheum ribes and its application , 2022, Bulletin of Materials Science.
[20] J. Miao,et al. A wax gourd flesh-derived porous carbon activated by different activating agents as lithium ion battery anode material , 2021, Journal of Materials Science: Materials in Electronics.
[21] S. Kandasamy,et al. Synthesis of activated carbon from black liquor for the application of supercapacitor , 2021, Journal of Materials Science: Materials in Electronics.
[22] Mouloud Denai,et al. A Technical analysis investigating energy sustainability utilizing reliable renewable energy sources to reduce CO2 emissions in a high potential area , 2021, Renewable Energy.
[23] K. Tennakone,et al. Graphite-type activated carbon from coconut shell: a natural source for eco-friendly non-volatile storage devices , 2021, RSC advances.
[24] Y. Ahn,et al. An enhanced electrochemical energy storage performance based on porous activated carbon and hard carbon derived from natural maple leaf , 2021, Journal of Materials Science: Materials in Electronics.
[25] Malarvizhi Muthu Balasubramanian,et al. Groundnut shell–derived porous carbon-based supercapacitor with high areal mass loading using carbon cloth as current collector , 2020, Ionics.
[26] D. Mohamed,et al. Roasted date palm seeds (Phoenix dactylifera) as an alternative coffee: chemical composition and bioactive properties , 2020, Biomass Conversion and Biorefinery.
[27] Feiqiang Guo,et al. Synthesis of biomass-based porous graphitic carbon combining chemical treatment and hydrothermal carbonization as promising electrode materials for supercapacitors , 2020, Ionics.
[28] S. Shi,et al. Self-support wood-derived carbon/polyaniline composite for high-performance supercapacitor electrodes , 2019, Bulletin of Materials Science.
[29] Jin‐Long Hong,et al. Areca nut–derived porous carbons for supercapacitor and CO2 capture applications , 2019, Ionics.
[30] R. Teimuri‐Mofrad,et al. Green synthesis of carbon nanotubes@tetraferrocenylporphyrin/copper nanohybrid and evaluation of its ability as a supercapacitor , 2019, Journal of Organometallic Chemistry.
[31] H. Devianto,et al. Activated carbon from citric acid catalyzed hydrothermal carbonization and chemical activation of salacca peel as potential electrode for lithium ion capacitor’s cathode , 2019, Ionics.
[32] Guoying Wang,et al. A hydrothermal carbonization process for the preparation of activated carbons from hemp straw: an efficient electrode material for supercapacitor application , 2019, Ionics.
[33] Chinwe O. Ikpo,et al. Maize (Zea mays L.) fresh husk mediated biosynthesis of copper oxides: Potentials for pseudo capacitive energy storage , 2019, Electrochimica Acta.
[34] Zhen Wang,et al. Hyperporous Carbon from Triptycene‐Based Hypercrosslinked Polymer for Iodine Capture , 2019, Advanced Materials Interfaces.
[35] Junyou Shi,et al. Waste fruit grain orange–derived 3D hierarchically porous carbon for high-performance all-solid-state supercapacitor , 2019, Ionics.
[36] R. Rahman,et al. Effect of the Roasting Conditions on the Physicochemical, Quality and Sensory Attributes of Coffee-Like Powder and Brew from Defatted Palm Date Seeds , 2019, Foods.
[37] R. Teimuri‐Mofrad,et al. Synthesis and characterization of ferrocene-functionalized reduced graphene oxide nanocomposite as a supercapacitor electrode material , 2019, Journal of Organometallic Chemistry.
[38] Ming-Qiang Zhu,et al. Activated carbons prepared by hydrothermal pretreatment and chemical activation of Eucommia ulmoides wood for supercapacitors application , 2018, Industrial Crops and Products.
[39] Xiaowei Lu,et al. Biomass carbon materials derived from macadamia nut shells for high-performance supercapacitors , 2018, Bulletin of Materials Science.
[40] Aibing Chen,et al. Porous carbon derived from waste polystyrene foam for supercapacitor , 2018, Journal of Materials Science.
[41] Michael Pecht,et al. A review of fractional-order techniques applied to lithium-ion batteries, lead-acid batteries, and supercapacitors , 2018, Journal of Power Sources.
[42] Hongngee Lim,et al. How Did Nickel Cobaltite Reinforced Carbon Microfibre Symmetrical Supercapacitor Fare Against A Commercial Supercapacitor , 2017 .
[43] Gang Wang,et al. Flute type micropores activated carbon from cotton stalk for high performance supercapacitors , 2017 .
[44] M. Jaroniec,et al. From waste Coca Cola® to activated carbons with impressive capabilities for CO2 adsorption and supercapacitors , 2017 .
[45] Xiaodong Li,et al. High-performance supercapacitors and batteries derived from activated banana-peel with porous structures , 2016 .
[46] Jicheng Zhou,et al. Nitrogen and Oxygen-Doped Hierarchical Porous Carbons from Algae Biomass: Direct Carbonization and Excellent Electrochemical Properties , 2016 .
[47] Christopher R. Swartz,et al. Hemp-derived activated carbons for supercapacitors , 2016 .
[48] Lan Wang,et al. From environmental pollutant to activated carbons for high-performance supercapacitors , 2016 .
[49] V. Selvamani,et al. Garlic peel derived high capacity hierarchical N-doped porous carbon anode for sodium/lithium ion cell , 2016 .
[50] Shaomin Li,et al. Porous structure design of carbon xerogels for advanced supercapacitor , 2015 .
[51] Julie Ségalini,et al. Effect of pore texture on performance of activated carbon supercapacitor electrodes derived from olive pits , 2015 .
[52] Mingbo Wu,et al. Enteromorpha based porous carbons activated by zinc chloride for supercapacitors with high capacity retention , 2015 .
[53] S. Nair,et al. Composite supercapacitor electrodes made of activated carbon/PEDOT:PSS and activated carbon/doped PEDOT , 2013, Bulletin of Materials Science.
[54] Peihua Huang,et al. Ultrahigh-power micrometre-sized supercapacitors based on onion-like carbon. , 2010, Nature nanotechnology.
[55] A. Mohamed,et al. Preparation of carbon molecular sieve from lignocellulosic biomass: A review , 2010 .
[56] R. Ruoff,et al. Review of Best Practice Methods for Determining an Electrode Material's Performance for Ultracapacitors , 2010, 1005.0805.
[57] H. Oda,et al. Modification of the oxygen-containing functional group on activated carbon fiber in electrodes of an electric double-layer capacitor , 2006 .
[58] Y. Liu,et al. Effects of activation time on the electrochemical capacitance of activated carbon nanotubes , 2006 .
[59] C. Olivier,et al. Biomass-derived carbon electrodes for supercapacitors and hybrid solar cells: towards sustainable photo-supercapacitors , 2021, Sustainable Energy & Fuels.