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Activated carbons derived from coconut shells as high energy density cathode material for Li-ion capacitors

机译：椰子壳衍生的活性炭用作锂离子电容器的高能量密度阴极材料

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In this manuscript, a dramatic increase in the energy density of ~ 69 Wh kg⁻¹ and an extraordinary cycleability ~ 2000 cycles of the Li-ion hybrid electrochemical capacitors (Li-HEC) is achieved by employing tailored activated carbon (AC) of ~ 60% mesoporosity derived from coconut shells (CS). The AC is obtained by both physical and chemical hydrothermal carbonization activation process, and compared to the commercial AC powders (CAC) in terms of the supercapacitance performance in single electrode configuration vs. Li. The Li-HEC is fabricated with commercially available Li4Ti5O12 anode and the coconut shell derived AC as cathode in non-aqueous medium. The present research provides a new routine for the development of high energy density Li-HEC that employs a mesoporous carbonaceous electrode derived from bio-mass precursors.

机译：在此手稿中，通过采用量身定制的方法，锂离子混合电化学电容器（Li-HEC）的能量密度显着提高了〜69 Wh kg ^{-1 ，并具有出色的循环能力〜2000个循环活性炭（AC）的中孔度约60％来自椰子壳（CS）。 AC是通过物理和化学水热碳化活化过程获得的，就单电极配置与Li的超电容性能而言，与市售AC粉（CAC）进行了比较。 Li-HEC由市售的Li4Ti5O12阳极和椰子壳衍生的AC作为阴极在非水介质中制成。本研究为开发高能密度Li-HEC提供了新的程序，该方法采用了源自生物质前体的中孔碳质电极。}

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期刊名称 Scientific Reports
作者
Akshay Jain; Vanchiappan Aravindan; Sundaramurthy Jayaraman; Palaniswamy Suresh Kumar; Rajasekhar Balasubramanian; Seeram Ramakrishna; Srinivasan Madhavi; M. P. Srinivasan;
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年(卷),期 -1(3),-1
年度 -1
页码 3002
总页数 6
原文格式 PDF
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专利

1. Activated carbons derived from coconut shells as high energy density cathode material for Li-ion capacitors [J] . Akshay Jain, Vanchiappan Aravindan, Sundaramurthy Jayaraman, Scientific reports. . 2013,第1期

机译：椰子壳衍生的活性炭，用作锂离子电容器的高能量密度阴极材料
2. Toward high energy-density and long cycling-lifespan lithium ion capacitors: a 3D carbon modified low-potential Li2TiSiO5 anode coupled with a lignin-derived activated carbon cathode [J] . Jin Liming, Gong Ruiqi, Zhang Weichao, Journal of Materials Chemistry, A. Materials for energy and sustainability . 2019,第14期

机译：朝向高能量密度和长循环寿命锂离子电容器：3D碳改性低电位Li2TisiO5阳极与木质素衍生的活性炭阴极耦合
3. Beyond Activated Carbon: Graphite-Cathode-Derived Li-Ion Pseudocapacitors with High Energy and High Power Densities [J] . Wang Gang, Oswald Steffen, Loeffler Markus, Advanced Materials . 2019,第14期

机译：超越活性炭：具有高能量和高功率密度的石墨阴极锂离子伪电容器
4. The effect of activation agent on surface morphology, density and porosity of palm shell and coconut shell activated carbon [C] . A. M. Leman, S. Zakaria, M. N. M. Salleh, Electronic and Green Materials International Conference . 2017

机译：活化剂对棕榈壳与椰壳活性炭表面形态，密度和孔隙率的影响
5. Preparation of LithiumManganeseSilicate/Carbon and Lithium Fluoride/Iron/Carbon Nanofiber Cathode Materials for High-Energy Li-Ion Batteries. [D] . Zhang, Shu. 2012

机译：硅酸锰锰/碳和氟化锂/铁/碳纳米纤维阴极材料用于高能锂离子电池。
6. Fabrication of high-performance dual carbon Li-ion hybrid capacitor: mass balancing approach to improve the energy-power density and cycle life [O] . Tandra Panja, Jon Ajuria, Noel Díez, -1

机译：高性能双碳锂离子混合电容器的制造：质量平衡方法可提高能量-功率密度和循环寿命
7. Enhancement of LiFePO4 (LFP) Electrochemical PerformanceTthrough the Insertion of Coconut Shell Derived rGO – Like Carbon as Cathode of Li-ion Battery [O] . Eka Suarso, Firsta Agung Setyawan, Achmad Subhan, 2021

机译：LiFePO4（LFP）电化学性能的增强插入椰壳壳衍生的rgo样碳作为锂离子电池的阴极

Activated carbons derived from coconut shells as high energy density cathode material for Li-ion capacitors

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