乌拉草基碳材料的储气性能

在不添加外源性化学活化剂的条件下直接碳化乌拉草制备了多孔碳材料Ula C-950-HF.样品的碳含量高达93%,并且显示出部分石墨化的趋势.热重分析(TGA)结果显示样品具有很高的热稳定性(400℃前失重仅3%).N_2吸附-脱附测试结果表明样品的孔结构以微孔为主(峰值在1.1 nm),并有少量的介孔,总体的孔分布范围较窄,孔结构为有利于甲烷吸附的狭缝状.体积法测试结果表明,在298 K,3.5 MPa条件下,乌拉草基多孔碳材料Ula C-950-HF的甲烷储存能力达到208 mg/g(质量分数17%)或体积容量达到232 m L/m L.通过对产品的孔结构绘制模型并进行分析,从理论上初步解释了样品拥有较高的高压甲烷储存能力的原因.     

糖蜜基多孔碳球电极材料的制备及应用

以工业制糖的副产物糖蜜为新型碳源,替代传统多孔碳生产原料,制备出性能优异的多孔碳球超级电容器电极材料;探索了制备方法,优化了反应条件.利用全功能表面吸附仪、扫描电子显微镜及电化学方法对材料的结构、形貌和电化学性能进行了表征.结果表明,制得的多孔碳球比表面积高达2547 m~2/g,且展现出优异的双电层电容性(170.5 F/g).本研究可解决制糖企业对糖蜜无法大规模利用的问题,并为多孔碳的制备寻求新方法.     

褐煤基多孔炭/CoNi_2S_4复合材料的制备及电容特性研究

以宝清褐煤为原料,使用KOH溶液萃取、活化后制得煤基多孔炭,并利用简单的水热法将褐煤基多孔碳与CoNi_2S_4复合,制备复合电容电极材料。考察了不同碳添加量对褐煤基多孔碳/CoNi_2S_4复合材料电化学性能的影响,结果表明,碳添加量过高或过低都不利于复合材料比电容的提升,而碳添加量为37%的褐煤基多孔碳/CoNi_2S_4复合材料具有较高的比电容和良好的循环性能,该复合电极在4 A/g电流密度下,比电容达到1318.2 F/g,在4000次充放电循环后电容保持率为80.9%。     

多孔碳材料的化学气相后处理及其超级电容性能

以廉价的椰壳为原料制备了高比表面积的多孔碳材料,然后在密闭的反应釜中以硝酸蒸汽对多孔碳材料进行了后处理,制备了亲水性更好的多孔碳材料。采用扫描透射电子显微镜(TEM)、物理吸附、X射线粉末衍射(XRD)、拉曼光谱(Raman)和接触角测试对材料的微观形貌、孔道结构、组成和亲水性进行了表征,探究了不同温度下硝酸蒸汽对多孔碳材料的形貌、结构的影响,并采用循环伏安法、恒电流充放电法和交流阻抗法考察了多孔碳材料的超级电容性能。结果表明,经过硝酸蒸汽处理后的多孔碳材料的比表面积和孔体积均有所降低,且随着处理温度的升高,降低得更加明显,而亲水性却越来越好。电化学测试结果表明,经过100℃硝酸蒸汽处理的多孔碳材料(CSC-100)具有最佳的超级电容性能。在以6 mol·L^-1 KOH为电解液的三电极体系中,当电流密度为0.5 A·g^-1时CSC-100的比电容可达452.9 F·g^-1,而未经硝酸蒸汽处理的多孔碳材料(CSC)的比电容仅为350.4 F·g^-1。电容贡献分析表明CSC-100良好的亲水性和表面官能团不仅提高了双电层电容,也提高了赝电容。     

壳聚糖制备多孔炭及其在电化学超级电容器中的应用(英文)

以壳聚糖为原料在 600、700、800和900℃直接炭化制备多孔炭 C-600,C-700, C-800 和C-900,其BET比表面积分别为278、461、515和625 m2·g-1.用恒流充放电和循环伏安法表征了其电化学性能. 结果表明, 由 C-800 制备电极的循环伏安图形更接近矩形, 在恒电流充放电实验中阴极和阳极过程基本对称, 说明该电极具有较好的电容性能.在 50 mA·g-1 的电流密度下,C-600、C-700、C-800和C-900的电容分别为96、120、154 和 28 F·g-1.由 C-800 制备电极的循环充放电稳定性好, 电流密度为1 A·g-1循环1000次后电容损失小于2%,说明壳聚糖制备多孔碳具有作为超级电容器电极材料的潜在价值. 同时还考察了不同浓度的电解液对C-800电化学性质的影响,发现在KOH浓度为 30%时的电容最大.依据实验结果,对多孔炭制备及其电化学性质间的关系进行了探讨.     

混合盐活化胖大海基多孔炭的制备及超级电容器电极材料性能

利用浸泡后的胖大海为碳源, 氯化锌和氯化锂混合盐作为活化剂, 采用炭化胖大海(PC-1)、添加氯化锌(PC-2)或添加氯化锌/氯化锂(PC-3)的胖大海的方法制备了3种多孔碳材料, 并通过三电极体系测试电极材料的电化学性能。结果表明, 3种碳材料在电流密度为0.5 A/g的比电容分别为69、132和228 F/g; 当电流密度增加至10 A/g时, PC-3的比电容仍高达166 F/g, 具有良好的倍率性能。该实验表明, 通过氯化锌/氯化锂复合盐活化胖大海分级多孔碳可作为高性能超级电容器电极材料。     

基于聚多巴胺的氮掺杂碳材料的制备及其电化学性能

多孔碳材料由于高的比表面积、优异的电子传导率、良好的化学稳定性等优点在超级电容器电极材料领域被广泛研究。 碳材料的组成及表面孔结构直接影响其电化学性能,为进一步提高碳材料的电容性能,本文首次以聚多巴胺球为前体,KOH为活化剂,通过高温碳化成功制备了良好电化学性能的氮掺杂多孔碳材料。 通过扫描电子显微镜(SEM)、透射电子显微镜(TEM)、 X射线粉末衍射(XRD)、傅里叶变换红外光谱(FT-IR)、X射线光电子能谱(XPS)和Raman光谱等对所制备的氮掺杂多孔碳材料进行了形貌及结构组成的表征。 在6 mol/L KOH电解液中, 采用循环伏安、恒电流充放电对多孔碳材料的电化学性能进行了研究。 结果表明,由于双电层电容和赝电容的协同作用,在电流密度为1 A/g时,材料的比电容可达269 F/g,充放电循环1000圈后电容仍可保留初始值的93.5%。     

超级电容器用含氮碳与含氮碳/炭气凝胶复合电极材料的制备和性能研究

采用原位聚合法合成聚苯胺(PAIN)及聚苯胺/炭气凝胶(PAIN/CA)复合材料,经过高温裂解制备含氮碳(NC)及含氮碳/炭气凝胶复合材料(NC/CA),再以KOH为活化剂对其进行活化,制备活化含氮碳(ANC)及活化含氮碳/炭气凝胶复合材料(ANC/CA)。采用扫描电镜、循环伏安、恒流充放电以及电化学阻抗等方法进行性能测试,结果表明,由于KOH的活化作用,含氮碳材料的粒径明显变小,其比电容值为138 F/g,高于未活化含氮碳材料(98 F/g),ANC/AC3复合材料电极的比电容值比ACA电极(88 F/g)高,达到127 F/g。     

海藻基含杂原子碳材料的制备及电化学性质

以天然海藻为原料,经条件优化制备了含杂原子的碳材料Sar CW-900及Lam CW-900,对其形貌、元素成分、孔性质和石墨化程度进行分析并讨论其活化机理.将2种材料作为电化学电容器及锂离子电池的电极材料活性物质,分别进行电化学性能测试.结果表明,Sar CW-900及Lam CW-900在被用作电化学电容器电极材料时,比电容分别为106 F/g及85 F/g,经5000次循环伏安稳定性测试,比电容值稳定在101 F/g及81 F/g,分别降低不到4%和5%,是理想的电容器电极材料;在被用作锂离子电池电极材料时,经100次循环比容量分别保持在100. 3及33. 9 mA·h/g,低于纯石墨的理论值,但具有较高的稳定性.     

十二烷基硫酸钠辅助制备高电容性能多孔碳

本工作通过一步水浴法制备高氮/氧含量密胺树脂(MF), 引入阴离子型表面活性剂十二烷基硫酸钠(SDS)改变聚合物的反应历程, 使进入SDS胶束中的三聚氰胺与甲醛在盐酸催化条件下进行聚合反应, 高温碳化后成功制备MF衍生多孔碳材料. 对MF衍生多孔碳材料分别进行了扫描电镜、比表面积等表征, 结果表明, 其具有多孔互穿网络结构, 比表面积高达387.86 m²?g^-1, 且孔径分布适宜(3.62 nm). 作为超级电容器(SCs)电极材料, 在1.0 A?g^-1下的比电容值为349.6 F?g^-1, 20.0 A?g^-1时(254.6 F?g^-1)仍能维持1.0 A?g^-1时73.0%的电容保持率, 倍率性能优异. 该样品在10.0 A?g^-1下循环15000次后的比电容值几乎没有衰减, 循环稳定性能优越. 此研究结果表明SDS可辅助提升MF衍生多孔碳材料的电容性能, 发展潜力巨大.     

高功率超级电容器用介孔炭电极材料

以纳米CaCO3为模板、蔗糖为前躯体制备超级电容器用介孔炭电极材料.材料的结构由氮吸附、TEM表征,借助恒流充放电、循环伏安和交流阻抗评价了其在6 mol.L-1KOH电解液中的电化学电容性能.结果表明,蔗糖基介孔炭的比表面积606 m2/g,富含10~30 nm的介孔.恒流放电法测得介孔炭在电流密度50 mA/g下的比电容为125 F/g,大电流倍率性能特别突出.电流密度增大到20 000 mA/g,比电容还保持有88F/g,远高于进口电容炭,该介孔炭是一种很有前景的高功率超级电容器炭电极材料.     

基于玉米秸秆合成的多孔生物质炭材料及其电化学储能

以玉米秸秆为原料,合成了高比表面积(2167 m²/g)的多孔生物质炭材料。 优化实验条件即可获得性能最佳的生物质炭电极材料,其在电流密度为1 A/g时的比电容高达390 F/g。 更重要的是,以所得最佳多孔生物质炭为电极材料,3 mol/L 的KOH溶液为电解质,组装了液相对称超级电容器。 该超级电容器在功率密度为818 W/kg时,其能量密度高达7 Wh/kg,在循环10000圈后的电容保持率为91.1%。 同时,将两个这种超级电容器串联充电之后,能够点亮15个LED灯并驱动小风扇正常工作。 这些结果表明,将基于玉米秸秆的多孔生物质炭作为先进电极材料应用于超级电容器具有较大的实际应用价值。     

溶胶凝胶方法制备纳米氧化钌的超电容特性

A kind of ruthenium oxide with smaller particles and higher porosity was prepared by a sol-gel process with RuCl3·xH2O and NaHCO3 solution. Several details concerning this new material, including crystal structure,particle size as functions of the temperature, and electrochemical properties were also reported. The optimal annealing temperature was 210 ℃ and the powder annealed at this temperature had a rate capacitance of 541 F/g. In addition, the rate capacitance of the composite electrode reached 802 F/g after 10% carbon black was added, much higher than any previously reported value. High energy density supercapacitors were built with the newly discovered electrode material. Energy densities as high as 67 J/g were obtained based on the RuO2 ·xH2O alone. By introducing the highly porous carbon black into the electrode, energy densities great than 100 J/g could be achieved. The power density of the capacitor was enhanced significantly.     

Fabrication of high-performance supercapacitor using date leaves-derived submicron/nanocarbon

Offering a suitable and low-cost electrode material is one of the most important and challenging demands in supercapacitor research. In this aspect, carbon prepared from biomass by simply pyrolysis and ball milling could be one ideal electrode material for supercapacitor applications. Hence, a novel type of submicron/nanocarbon was prepared from date leaves by simple pyrolysis and ball milling. After morphological and chemical characterizations, the prepared carbon was used as the electrode material upon immobilizing on a steel substrate (current collector) to fabricate a high-performance symmetric supercapacitor. The fabricated supercapacitor took advantage of the carbon's electric double layer capacitance behaviour and pseudocapacitance behaviour of heteroatoms present in the carbon. The developed supercapacitor device provides significant charging/discharging using the optimum electrolyte (0.1 M sulfuric acid). That manifested with a high specific capacitance of (～107 F/g) and maintained above 92% of its initial capacitance after 1000 charge/discharge cycles. Furthermore, the supercapacitor provides an energy density of ～10 Wh/Kg at a power density of ～200 W/Kg. This work provides an inexpensive, high-performance supercapacitor that depends on the biomass (date palm leaves) and nominates it as a capable candidate for mass-product in the future.     

Exfoliated graphite nanosheets/carbon nanotubes hybrid materials for superior performance supercapacitors

Nanostructured hybrid material of exfoliated graphite nanosheets and carbon nanotubes (GNSNT) served as supercapacitor electrode materials was presented. The nanostructured hybrid was prepared by a facile chemical reduction method. The hybrid material was characterized by X-ray diffraction technique, transmission electron microscopy, scanning electron microscopy, cyclic voltammetry, galvanostatic charge/discharge cycling, and four-point probe conductivity measurement to represent a well-defined nanostructure possessing a vast number of active sites and delivering the ingredients for a fast effective charge separation network. Our results clearly demonstrated that the hybrid possess a superior performance. A specific capacitance value 266 F/g was obtained for GNSNT hybrid electrode at a current density of 0.1 A/g, while it was only 185 F/g for exfoliated graphite nanosheets (GNS). At a higher current density of 2 A/g, the GNSNT electrode still keeps a specific capacitance of 220 F/g, which is more than double that of GNS. This synergistic effect of the nanostructured hybrid material offers an effective network for charge separation and therefore renders a significantly enhanced specific capacitance and rate capability.     

Nitrogen-doped porous carbon coated on MnCo2O4 nanospheres as electrode materials for high-performance asymmetric supercapacitors

Spinel-based nanostructured materials are commonly used as promising electrode materials for supercapacitor applications. The combination of heteroatom-doped carbon material with spinel oxides substantially improves the specific capacitance and cyclic stability. In this work, dopamine-derived nitrogen-doped carbon was coated on spinel phase MnCo₂O₄ nanospheres using simple solvothermal and calcination methods. Surface morphology and the crystalline structure of the prepared MnCo₂O₄@Nitrogen-doped carbon were confirmed by FESEM and X-ray diffraction. The electrochemical performance of MnCo₂O₄@Nitrogen-doped carbon electrode material was analyzed by cyclic voltammetry, galvanostatic charge–discharge, and electrochemical impedance spectroscopy techniques. MnCo₂O₄@nitrogen-doped carbon exhibits the highest specific capacitance of 1200 F/g compared to MnCo₂O₄ spheres are 726 F/g at 1 A/g and exhibits excellent cyclic stability (capacitance retention of 87% at 7 A/g after 3000 cycles). The enhanced performance of the composite might be benefitted from the synergistic effect between nitrogen-doped carbon on porous MnCo₂O₄ spheres. Furthermore, an asymmetric supercapacitor device was fabricated by using the optimized composition of MnCo₂O₄@NC-2 as a positive electrode and nitrogen, sulfur-doped reduced graphene oxide (NS-rGO) as a negative electrode, respectively. This asymmetric supercapacitor device achieves a maximum energy density of 61.0 Wh/kg at a power density of 2889 W/kg and possesses excellent capacitance retention of 95% after 5000 cycles at 7 A/g.     

镍钴氢氧化物的制备及其电化学性能

采用化学共沉淀法成功制备了片状镍钴氢氧化物,并探究了不同镍钴物质的量比对样品形貌及电化学性能的影响。通过X射线衍射(XRD)、扫描电子显微镜(SEM)、X射线光电子能谱仪(XPS)及比表面积孔径分析仪(BET)对样品的结构、形貌进行了表征,并利用循环伏安法、恒电流充放电法等对其电化学性能进行了分析。结果表明,n(Ni)∶n(Co)=4∶1的样品直接用作电极材料时,具有最好的电化学性能:在0.5 A/g的电流密度下拥有1852 F/g的高比容量;电流密度增大20倍时,仍拥有1330 F/g的高比容量。以镍钴氢氧化物为正极,活性炭为负极组装的非对称式超级电容器在346 W/kg的功率密度下,能量密度达52 Wh/kg,在循环10000圈之后电容保持率为92%。优异的电化学性能表明,片状镍钴氢氧化物是很有应用潜力的电极材料之一。     

N-doped honeycomb-like porous carbon towards high-performance supercapacitor

Biomass-derived porous carbon with developed pore structure is critical to achieving high performance electrode materials. In this work, we report a grape-based honeycomb-like porous carbon (GHPC) prepared by KOH activation and carbonization, followed by N-doping (NGHPC). The obtained NGHPC exhibits a unique honeycomb-like structure with hierarchically interconnected micro/mesopores, and high specific surface area of 1268 m²/g. As a supercapacitor electrode, the NGPHC electrode exhibits a remarkable specific capacitance of 275 F/g at 0.5 A/g in a three-electrode cell. Moreover, the NGHPC//NGHPC symmetric supercapacitor displays a high energy density of 12.6 Wh/kg, and excellent cycling stability of approximately 95.2% capacitance retention after 5000 cycles at 5 A/g. The excellent electrochemical performance of NGHPC is ascribed to its high specific surface area, honeycomb-like structure and high-content of pyrodinic-N (36.29%). It is believed that grape-based carbon materials show great potential as advanced electrode materials for supercapacitors.     

氮掺杂石墨烯量子点/MOF衍生多孔碳纳米片构筑高性能超级电容器

首先采用溶液法在碳布上生长Co-MOF二维纳米片,通过高温退火和刻蚀后得到MOF衍生多孔碳纳米片。以Co-MOF衍生的多孔碳纳米片/碳布(CNS/CC)作为碳基骨架,采用电化学沉积法负载高活性氮掺杂石墨烯量子点(N-GQDs),制备得到分级多孔结构的N-GQD/CNS/CC复合材料。组装成自支撑且无粘结剂的N-GQD/CNS/CC电极,当电流密度为1 A·g~(-1)时,其比电容高达423 F·g~(-1)。通过储能机制和电容贡献机制的研究表明,在碳纤维上原位生长的具有高双电层电容的CNS和表面负载具有高赝电容的N-GQDs之间相互协同作用,使得N-GQD/CNS/CC电极具有高电容性能,是一种理想的超级电容器电极材料。电极材料的高导电、分级多孔结构有利于电子的传输和电解质离子的扩散,具有良好的动力学性能,能快速充放电和具有优异的倍率特性。将电极组装成对称型超级电容器,功率密度为250 W·kg~(-1)时对应的能量密度达到7.9 Wh·kg~(-1),且经过10 000次循环后电容保持率为91.2%,说明氮掺杂石墨烯量子点/MOF衍生多孔碳纳米片复合材料是一种电化学性能稳定的具有高电容性能的全碳电极材料。     

CoNi_2S_4 Microspheres Prepared by One-pot Hydrothermal Reaction as Supercapacitor

A microsphere discrete structure of CoNi_2S_4 was prepared through one-pot hydrothermal reaction and characterized by FTIR, XRD and SEM. The as-prepared CoNi_2S_4 served as a supercapacitor, showing a specific capacitance of 1129.5 F/g with over 99% coulombic efficiency at a current density of 4 A/g in 3 M KOH. And after 3000 cycles of charge and discharge tests, 92.3% of its initial capacitance can be still maintained. The results demonstrate that the material is promising as an electrode material for supercapacitors in energy storage.