High-performance supercapacitors of hydrous ruthenium oxide/mesoporous carbon composites

The amorphous hydrous ruthenium oxide/mesoporous carbon composites (denoted as RuO₂·xH₂O/MC), obtained by loading small amount of amorphous hydrous ruthenium oxide nanoparticles ranged from 0.9 to 5.4% by weight of Ru (denoted as RuO₂·xH₂O) on mesoporous carbon (MC), were investigated for the first time and were used for supercapacitors. Electrochemical measurements showed that RuO₂·xH₂O/MC composites not only have an enhanced specific capacitance but also retain the superior rate capability of MC. The RuO₂·xH₂O/MC composite with Ru loading of 3.6 wt% exhibited an increase of the specific capacitance of approximately 57% (from 115 to 181 F/g) at the scan rate of 25 mV s⁻¹ in 0.1 M H₂SO₄ aqueous electrolyte. The specific capacitance based on the mass of RuO₂ was estimated to be 1,527 F/g, by subtracting the contribution from MC in the composite. Cycle performance tests for RuO₂·xH₂O/MC composite (3.6 wt% Ru) showed that approximately 2.8% loss of the total capacitance was observed after 1,000 cycles.     

High-performance organic electrolyte supercapacitors based on intrinsically powdery carbon aerogels

Powdery carbon aerogel with an ideal hierarchical pore structure shows impressive capacitive performances when utilized as electrodes for organic electrolyte supercapacitors.     

Lignin derived porous carbon with favorable mesoporous contributions for highly efficient ionic liquid-based supercapacitors

Lignin and its derivatives hold great potential in developing high performance porous carbon materials for supercapacitors due to the versatile features of high carbon content, abundant multifunctional groups, low cost, and environmental benefits. Unfortunately, their derived porous carbon generally has the features of unfavorable microporous-dominated morphologies and low specific surface area (SSA) attributed from the highly-branched structure of lignin, which are hardly suitable for the supercapacitors with ionic liquid (IL) electrolyte, leading to poor energy density and rate capability. Herein, porous carbon materials with desirable mesoporous contributions from sodium lignosulphonate are designed via a facile template method. Such rich mesoporisity carbon materials not only possess with three-dimensional interconnected network, large SSA, as well as favorable pore size distribution for accelerated ion and electron mass transfer, but also feature low heteroatom content for high electrochemical stability. Consequently, the optimal electrode exhibits a high capacitance of 166 F/g at 0.5 A/g, superior rate performance (59 Wh/kg at 59 kW/kg), as well as impressive cycle life with good capacitance retention of 93.1% in EMIBF₄ electrolytes. The present work opens a new avenue to design porous carbon materials with high mesopore properties from lignin for effective compatibility with IL electrolyte in high-performance supercapacitors.     

Temperature stable supercapacitors based on ionic liquid and mixed functionalized carbon nanomaterials

The ionic liquid 1-butyl-2,3-dimethylimidazolium bis(trifluoromethylsulfonyl)imide (BDMIM-TFSI) showed a conductivity of 1.65?mS cm^?1 and an electrochemical stability window of 4.4?V at room temperature. Two types of electrodes based on carbon nanomaterials were prepared: (1) with alternating layers of two oppositely charged functionalized double-walled carbon nanotubes (DWCNTs) and (2) with the functionalized DWCNTs and graphene oxide nanoplatelets. The electrodes presented a porous morphology and a connected pathway between the carbon nanotubes and graphene oxide platelets. Electrochemical capacitors based on the carbon nanomaterials and BDMIM-TFSI were produced in a stacking configuration and were characterized at 25?°C, 60?°C, and 100?°C. The supercapacitors with electrodes based on the three alternating layers of two oppositely charged DWCNTs and graphene oxide presented higher values of capacitance, which were attributed to a morphology favorable to providing ionic access to the carbonaceous surface. Box-like voltammetric curves were used to calculate the capacitance in a 4-V potential window at 100?°C.     

Ordered mesoporous silicon carbide-derived carbon for high-power supercapacitors

Micro/mesoporous carbon was prepared by chlorination of ordered mesoporous silicon carbide derived from magnesio-thermal reduction of templated carbon-silica precursors. These materials were then used as active materials for electrochemical capacitors and characterized in 1.5 M NEt₄BF₄/AN. The electrodes showed outstanding rate capability (90% of capacity retention at 1 V/s and time constant of 1 s) with high specific areal capacitance (0.5 F/cm² of electrode), that makes such hierarchical porous carbons promising for high power and energy density supercapacitors.     

High-performance titanium dioxide photocatalyst on ordered mesoporous carbon support

Anatase TiO₂ photocatalysts supported with the ordered mesoporous carbon, CMK-3, were synthesized by the incorporation of TiO₂ into CMK-3 followed by heating at 700 °C. The structural properties of the TiO₂ on CMK-3 were investigated by X-ray diffraction, nitrogen physisorption and electron microscopy techniques. In particular, TiO₂ was observed both inside and the external surface of CMK-3. The photocatalytic activity of TiO₂ on CMK-3 under UV-light exhibited higher efficiency in removing the Rhodamine 6G dye solution than the commercial photocatalyst P25 and TiO₂ on activated carbon. It was attributed to the synergistic effect of large surface area adsorption provided by mesoporous CMK-3 and the distinctive location of TiO₂ on the external surface of CMK-3.     

Flexible supercapacitors based on carbon nanotubes

This review provides an overview of recent progress towards the development of flexible supercapacitors based on macroscopic carbon nanotubes-based electrodes, including one-dimensional (1D) fibers, 2D films, and 3D foams, with a focus on electrode preparation and configuration design as well as their integration with other multifunctional devices.     

Organic salt-derived phosphorus-doped mesoporous carbon for high performance supercapacitors

Phosphorus-doped mesoporous carbons (PMCs) were prepared using a self-doping and self-templating approach via direct pyrolysis of sodium phytate (C₆H₁₇NaO₂₄P₆). The one-pot method allows simultaneous carbonization and P doping, eliminating the need for pre-synthesis or post-activation treatment. The C₆H₁₇NaO₂₄P₆ is the source of both carbon and phosphorus, and the nano-Na₄P₂O₇ particles produced during pyrolysis act as hard templates for the honeycomb mesoporous structure with high specific surface area (884–827 m²/g), large mesopore volume ratio (67%–75%) and rich phosphorus content (0.53–2.34 at%). As electrodes of supercapacitors in 6 mol/L KOH, the PMCs showed outstanding performance with a high capacitance of 202 F/g and excellent rate performance of 148 F/g at 30 A/g. In addition, the PMCs-based symmetrical supercapacitors can operate in an expanded working voltage of 0–1.6 V in 3 mol/L H₂SO₄ aqueous electrolytes with high-density energy of 11.8 Wh/kg.     

Partially graphitic micro- and mesoporous carbon microspheres for supercapacitors

Partially graphitic micro-and mesoporous carbon microspheres(GMMCMs)were synthesized using hydrothermal emulsion polymerization followed by KOH activation and catalytic graphitization.The resulting GMMCMs show micro-and mesopores with a specifc surface area of 1113 m2/g,regular spherical shape with diameters of 0.5–1.0 mm and a partially graphitic structure with a low internal resistance of 0.34 V.The graphitic carbons as electrode for supercapacitor exhibit a fast ion-transport and rapid charge–discharge feature,and a high-rate electrochemical performance.The typical GMMCM electrode shows a specifc capacitance of 220 F/g at 1.0 A/g,and 185 F/g under a high current density of20.0 A/g in a 6 mol/L KOH electrolyte.     

超级电容器用中孔炭复合电极材料研究进展

超级电容器是一类利用电化学双电层或电极材料在电极/溶液界面发生的氧化还原反应来存储能量的装置,除兼有常规电容器功率密度大和二次电池能量密度高的特点外,还具有可逆性好和循环寿命长等优点.本文重点介绍了近几年国内外对中孔炭材料、表面官能团修饰中孔炭材料、中孔炭-金属氧化物、中孔炭-导电聚合物等几类电极材料的研究现状;并且展望了超级电容器用中孔炭及其复合电极材料的当前研究热点和发展前景.     

Bi2O3 deposited on highly ordered mesoporous carbon for supercapacitors

A simple route has been employed to prepare nanosized Bi₂O₃ deposited on highly ordered mesoporous carbon. The electrochemical measurements reveal that, by loading only 10% Bi₂O₃ on the mesoporous carbon, the specific capacitance of the composite is improved by 62%, with the maximum value reaching 232 F g^?1 at a sweep rate of 5 mV s^?1. The specific capacitance of Bi₂O₃ is calculated and reaches 1305 F g^?1 at 1 mV s^?1. It is found that the mass transfer in the framework of the crystalline oxide is still difficult in spite of its nanosize, as evidenced by the decline of the specific capacitance of the Bi₂O₃ with the increase of the sweep rate. The cyclic life of composite materials is also measured and the capacitance only declines 21% after 1000 cycles.     

High-performance supercapacitors based on free-standing SiC@PEDOT nanowires with robust cycling stability

Conductive polymers as one of the candidate materials with pseudocapacitor behavior have inspired wide attentions, because of their high conductivity, fexibility, low cost and excellent processability.However, the intrinsically poor cycling stability induced by the volume change over the doping/dedoping redox process limits their practical applications. Herein, we report the exploration of electrodes with robust cycling capacity for supercapacitors(SCs), which are rationally designed by coating ...     

Physical and electrochemical characterization of activated carbons with high mesoporous ratio for supercapacitors based on ionic liquid as the electrolyte

A series of activated carbons with high mesoporous ratio were prepared by KOH reactivation based on activated carbon as the precursor. As the KOH/AC mass ratio was increased to 4:1, the mesoporous ratio increases from 60% to 76%, and the average pore size from 2.23 to 3.14?nm. Moreover, the specific capacitance for the activated carbon in ionic liquid 1-ethyl-3-methylmidazolium tetrafluoroborate ([EMIm]BF₄) can reach the maximum value of 189?F?g^?1 (8.0???F?cm^?2). In addition, the decrease of specific capacitance for activated carbons by KOH reactivation with current density increase shows two regimes, suggesting that activated carbons with high mesoporous ratio are much fit for charge?Cdischarge at larger current density.     

Synthesis of mesoporous carbon aerogels based on metal-containing ionic liquid and its application for electrochemical capacitors

Journal of Solid State Electrochemistry - Mesoporous carbon aerogels were prepared by sol-gel polycondensation of resorcinol and formaldehyde through ionic liquid/metal ions synergistic effect. The...     

掺氮介孔炭作为双功能材料用于氧还原与超级电容器

以壳聚糖为含氮碳源,正硅酸乙酯为软模板,硝酸镍为催化剂,通过简单的低温水热法及后续炭化,成功合成出掺氮介孔炭材料（NMC-1）.NMC-1含有多孔结构以及氮氧等杂原子,能提高其电催化性能、双电层电容与赝电容.由于NMC-1在碱液中表现出显著的催化氧还原反应活性和具有较高的超级电容器比电容（在0.2A/g时为252F/g）及好的循环稳定性,因此,它有可能作为一种可再生、环保的双功能材料同时应用于燃料电池与超级电容器领域.     

Converting eucalyptus leaves into mesoporous carbon for its application in quasi solid-state supercapacitors

A high performance activated carbon having pore diameter of 2.8 nm and specific surface area of 841.8 m² g^?1 is prepared by chemical activation of eucalyptus leaves using KOH as an activating agent. The chemically-treated eucalyptus leaves EL(T) as electrode material has a specific capacitance of 663.5 mF cm^?2 (equivalent to single electrode specific capacitance of 442.3 F g^?1) with solid polymer electrolyte. This active material has excellent rate capability and good cycle performance, over 95 % of the original capacitance is retained after 5,000 cycles. The energy density of 101.6 Wh kg^?1 and power density of 2.85 kW kg^?1 has been observed for EL(T) based quasi solid-state supercapacitors.     

Electrochemical performance of a novel ionic liquid derived mesoporous carbon

A novel nano-fibrillated mesoporous carbon (IFMC) was found to be an effective modifier in combination with ionic liquid 1-octylpyridinum hexafluorophosphate (OPFP) as a binder to give impregnated graphite electrodes with outstanding electrochemical performances.