三氧化钼/活性炭钠离子电化学电容器

以三氧化钼(MoO3)作为负极材料,活性炭(AC)作为正极材料,组成混合型电化学电容器.研究电容器在1 mol/L NaPF6的碳酸丙烯酯(PC)中的电化学性能,其电位窗为0～3V,能量密度和功率密度分达到33.0 W·h/kg和595.6W/kg,经1000次循环后容量为第20次的93.8％,库仑效率在经过20次循环后到95.1％以上.     

碳布负载的缺氧型Na2Ti3O7纳米带阵列作为高性能柔性钠离子电池负极材料

作为锂离子电池的理想替代品,钠离子电池因具有能源储备丰富、成本低廉等优点而受到人们的广泛关注。柔性便携式电子产品的发展亟需柔性储能器件的研制。因此,发展一种廉价、高性能的柔性钠离子电池负极材料成了科研工作者的共同目标。在此项工作中,我们通过简单的水热合成和热还原法发展了一种以柔性碳布为基底,与缺氧型的Na₂Ti₃O₇纳米带(NTO)构成三维阵列结构的新型柔性钠离子电池负极材料。复合材料(R-NTO/CC)的导电性和活性位点得到提高,电化学性能也大幅提升,在200 mA·cm^-2的电流密度下,实现100 mAh·cm^-2的面积比容量,且经过200次循环后仍保留最初电容值的80%。此外,这种电极还具有优良的倍率性能,当电流密度提高到400 mA·cm^-2时,仍保持69.7 mAh·cm^-2的面积比容量,是未引入氧空位材料的三倍之多。这种三维缺氧的电极材料可有效提高载流子浓度,缩短离子传输通道,从而大幅提升电极的电化学性能。此工作为设计合成高储钠性能的新型的负极材料提供了一种实用有效的策略。     

钛酸钠纳米管-碳复合材料用作钠离子电容电池负极材料

以二氧化钛、氢氧化钠溶液和葡萄糖作为初始原料,通过水热方法合成了钛酸钠纳米管-碳复合材料。 使用XRD和TEM等方法测试了材料的结晶情况和形貌, 通过氮气吸-脱附和热重实验测试了材料的孔结构和碳含量。 采用复合材料作为负极材料,和石墨正极材料配伍,组装成不对称型电容电池,在钠基有机系电解液中其电压可高达3.5 V。 探讨了负极材料的储能机理,并考察了正负极质量比对负极储钠容量的影响。 电化学性能测试结果显示,电容电池具有较高能量密度和功率密度,其数值分别为72 Wh/Kg和1256 W/Kg,电容电池也表现出了较好的循环稳定性,在0.17 A/g电流密度下,经1000次循环后容量保持率高达100%。     

碳布负载的缺氧型Na_2Ti_3O_7纳米带阵列作为高性能柔性钠离子电池负极材料（英文）

作为锂离子电池的理想替代品,钠离子电池因具有能源储备丰富、成本低廉等优点而受到人们的广泛关注。柔性便携式电子产品的发展亟需柔性储能器件的研制。因此,发展一种廉价、高性能的柔性钠离子电池负极材料成了科研工作者的共同目标。在此项工作中,我们通过简单的水热合成和热还原法发展了一种以柔性碳布为基底,与缺氧型的Na_2Ti_3O_7纳米带(NTO)构成三维阵列结构的新型柔性钠离子电池负极材料。复合材料(R-NTO/CC)的导电性和活性位点得到提高,电化学性能也大幅提升,在200 m A·cm~(-2)的电流密度下,实现100 m Ah·cm~(-2)的面积比容量,且经过200次循环后仍保留最初电容值的80%。此外,这种电极还具有优良的倍率性能,当电流密度提高到400 m A·cm~(-2)时,仍保持69.7m Ah·cm~(-2)的面积比容量,是未引入氧空位材料的三倍之多。这种三维缺氧的电极材料可有效提高载流子浓度,缩短离子传输通道,从而大幅提升电极的电化学性能。此工作为设计合成高储钠性能的新型的负极材料提供了一种实用有效的策略。     

二硫化钼-碳复合材料用作钠离子电容电池负极材料

采用水热方法合成了二硫化钼-碳复合材料(MoS_2-C)。使用X射线衍射,扫描电子显微镜,透射电子显微镜,氮气吸-脱附和热重分析等手段对材料进行了物性表征。研究了MoS_2-C储钠机理,将其用作有机系钠离子电容电池负极材料,组装了MoS_2-C/AC电容电池,研究了电容电池的电化学性能。测试结果显示电容电池具有较高比能量和比功率,也表现出了较好的循环稳定性,经1000次循环后容量保持率高达96%。     

以预锂化中间相碳微球为负极的锂离子电容器的电化学性能

以商品活性炭(AC)为正极, 预锂化中间相碳微球(LMCMBs)为负极, 组装成锂离子电容器(LICs). 用X射线衍射(XRD)对LMCMB 电极材料的晶体结构进行了表征和分析, 预锂化量(PIC)小于200 mAh·g^-1 时,LMCMB电极材料基本保持了原始的石墨晶体结构. 利用三电极装置, 测试了充放电过程中LICs 的正、负极及整电容器的电压变化曲线. 以LMCMB为电极, 锂离子电容器负极的工作电压变低, 并且电压曲线更加平坦, 同时正极也可以利用到更低的电压区间. 对比锂离子电容器MCMB/AC, LMCMB/AC在比能量密度、循环性能和库仑效率电化学性能方面都得到了改善. 在电压区间2.0-3.8 V 下, 100 次循环后, 放电比容量的保持率从74.8%增加到100%, 库仑效率从95%增加到100%. LMCMB/AC电容器容量不衰退的直接原因是由于AC正极极化变小. 在2.0-3.8 V和1.5-3.8 V电压区间内, LMCMB/AC锂离子电容器的比能量密度分别可达85.6和97.9 Wh·kg^-1.     

LiCoO_2和LiMn_2O_4在水系电解液中的赝电容研究

用溶胶-凝胶法合成了LiCoO2和LiMn2O4样品粉末。以LiCoO2和LiMn2O4电极为正极,活性炭(AC)电极为负极,分别组装成模拟非对称超级电容器AC/LiCoO2和AC/LiMn2O4,通过循环伏安、恒流充放电和电化学阻抗研究其电容性能。测试结果表明,这类非对称电容器在Li2SO4溶液中展示了较好的电容性能。在电压范围(0～1.4)V、电流密度为100mA·g-1时,AC/LiCoO2和AC/LiMn2O4电容器的初始比电容分别为45.9和44.6F·g-1。但在大电流密度下,AC/LiMn2O4具有更大的比电容和更好的循环性能。实验结果还表明,在水系电解液中,LiCoO2和LiMn2O4均是通过Li+脱嵌导致过渡元素(Co,Mn)价态变化所产生的赝电容来实现储能。     

钠离子电池硬碳负极储钠机理及优化策略

钠离子电池因具有成本低、安全性高等优势, 被认为是一种非常适合应用于大规模储能领域的电化学储能技术. 合适的负极材料是促进钠离子电池实现商业化的关键之一. 硬碳材料由于具有丰富的碳源、低成本、无毒环保, 且储钠电位低而被认为是最可能被实用化的钠离子电池负极材料. 然而硬碳负极的实际应用中也面临着首周库伦效率低、长循环稳定性不足以及倍率性能较差等问题, 近年来众多研究者致力于硬碳负极的性能优化研究, 本Review从结构调控、形貌设计、界面构造、电解液优化四方面总结了近年来钠离子电池硬碳负极的性能优化策略研究进展, 分析了每种优化策略的优点和不足, 并进一步讨论了钠离子电池硬碳负极实用化进程中面临的瓶颈问题和挑战.     

预嵌锂硬碳和软碳用于锂离子电容器负极的比较研究

锂离子电容器是一种应用前景广阔的电化学储能器件. 目前,活性炭作为锂离子电容器正极被广泛使用. 然而,锂离子电容器负极却有多种不同选择,如硬碳和软碳等碳材料. 本文使用两种具有不同结构和电化学特性的硬碳和软碳材料作为锂离子电容器负极,进行了对比研究. 研究表明,软碳相比于硬碳有更好的电子导电性和更高的可逆容量. 通过在电流范围0.1 ~ 12 A·g^-1下进行充放电测试,分别研究了两种碳基电极在不同涂覆厚度下的倍率性能. 结果显示,硬碳电极在大电流下有更好的倍率特性. 然后,以活性炭为正极,预嵌锂的硬碳和软碳为负极,锂片为锂源和参比电极,分别组装了三电极软包锂离子电容器. 根据三电极充放电测试,分别研究了不同预嵌锂量的硬碳和软碳所组装的锂离子电容器的电化学性能. 结果表明,合适的负极预嵌锂容量可以提升锂电容的能量密度、功率密度和循环稳定性. 最后,大容量硬碳和软碳基软包锂离子电容器被分别组装,软碳基锂电容实现了最高的能量密度21.2 Wh·kg^-1（基于整个器件质量）,硬碳基锂电容实现最高的功率密度5.1 kW·kg^-1.     

钠离子电池炭基负极材料研究进展

钠离子电池是目前新兴的低成本储能技术,因在大规模电化学储能中具有较好的应用前景而受到了国内外学者广泛的关注与研究。作为钠离子电池的关键电极材料之一,非石墨的炭质材料因具有储钠活性高、成本低廉、无毒无害等诸多优点,而被认为是钠离子电池实际应用时负极的最佳选择。本文详细综述了目前钠离子电池炭基负极材料的研究进展,重点介绍了炭质材料的储钠机理与特性,分析了炭材料结构与电化学性能之间的关系,探讨了其存在的问题,为钠离子电池炭基负极材料的发展提供有益的认识。     

Performance of PbO2/activated carbon hybrid supercapacitor with carbon foam substrate

PbO₂/activated carbon（AC） hybrid supercapacitor in H₂SO₄ with a carbon foam current collector is studied.The PbO₂/AC hybrid is designed with electrodeposited PbO₂ thin film as positive electrode to match with AC negative electrode.The discharge curve shows capacitive characteristics between 1.88 V and 0.65 V.The hybrid system exhibits excellent energy and power performance,with specific energy of 43.6 Wh/kg at a power density of 654.2 W/kg.The use of carbon foam current collector ensures stability of the PbO₂ electrode in H₂SO₄ environment.After 2600 deep cycles at 15 C high rate of charge/discharge,the capacity remains nearly unchanged from its initial value.     

Flower-like Cu5Sn2S7/ZnS nanocomposite for high performance supercapacitor

Due to the synergistic effect between ZnS and Cu₅Sn₂S₇, the ZnS can enhance electrochemical performance of pristine Cu₅Sn₂S₇.     

Friction of MoO3 Nanoflakes on Graphite Surface with an Ace-like Intercalation Layer

How water layer adsorbed on solid surface under ambient conditions affects the interfacial friction is a fundamental question for understanding the friction and lubrication phenomena in practical system. We investigate the formation of ice-like(IL) water layers on the hydrophobic surface of graphite with partially covered MoO₃ nanoflakes(NFs) using atomic force microscopy(AFM) based techniques. The IL water layers are found surrounding the MoO₃ NFs and also intercalated at the MoO₃/graphite interface, as proved by thickness measurements as well as local adhesion force and surface potential mappings. AFM manipulations carried out on MoO₃ NFs on graphite show that the presence of the IL water layers increases the frictional resistance of the interface. Comparing the results on continuous and discontinuous IL water layers, we can identify the different sliding interfaces in the two scenarios. The increased friction for MoO₃ NFs sliding on graphite with an intercalated water layer is attributed to the energy dissipation originated from the metastable nature of the IL layers.     

Design and Preparation of Graphene/Fe2O3 Nanocomposite as Negative Material for Supercapacitor

The development of high specific capacitance electrode materials with high efficiency, scalability and economic feasibility is significant for the application of supercapacitors, however, the synthesis of electrode material still faces huge challenges. Herein, graphene(G)/Fe₂O₃ nanocomposite was prepared via a simple hydrothermal method connected with subsequent thermal reduction process. Scanning electron microscopy(SEM) and transmission electron microscopy(TEM) results showed rod-like Fe₂O₃ nanoparticles were prepared and well-dispersed on graphene layers, providing a rich active site and effectively buffering the aggregation of Fe₂O₃ nanoparticles in the process of electrochemical reaction. The specific capacitance of the obtained G/Fe₂O₃ nanocomposite as negative electrode for supercapacitor was 378.7 F/g at the current density of 1.5 A/g, and the specific capacitance retention was 88.76% after 3000 cycles. Furthermore, the asymmetric supercapacitor(ASC) was fabricated with G/Fe₂O₃ nanocomposite as negative electrode, graphene as positive electrode, which achieved a high energy density of 64.09 W∙h/kg at a power density of 800.01 W/kg, maintained 30.07 W∙h/kg at a power density of 8004.89 W/kg, and retained its initial capacitance by 78.04% after 3000 cycles. The excellent result offered a promising way for the G/Fe₂O₃ nanocomposite to be applied in high energy density storage systems.     

基于阴离子-石墨嵌层化合物的电化学电容器

石墨可以在高电势下电化学可逆存储阴离子,有望在高电压储能器件中担当正极材料.本文介绍了基于阴离子-石墨嵌层化合物型正极材料的高比能电容器的研究进展,剖析了影响电容器性能的各方面因素,探讨了一系列表征相关电极材料储能机制的方法和手段,揭示了溶剂化效应对阴离子插嵌石墨正极电化学行为的关键性作用.并进一步概述了该种正极材料近年来在新型储能器件-双离子电池中的发展态势,展望了其应用前景和即将面临的潜在问题.     

基于NiCo2O4纳米片电极的非对称混合电容器

The looming global energy crisis and ever-increasing energy demands have catalyzed the development of renewable energy storage systems. In this regard, supercapacitors (SCs) have attracted widespread attention because of their advantageous attributes such as high power density, excellent cycle stability, and environmental friendliness. However, SCs exhibit low energy density and it is important to optimize electrode materials to improve the overall performance of these devices. Among the various electrode materials available, spinel nickel cobaltate (NiCo₂O₄) is particularly interesting because of its excellent theoretical capacitance. Based on the understanding that the performances of the electrode materials strongly depend on their morphologies and structures, in this study, we successfully synthesized NiCo₂O₄ nanosheets on Ni foam via a simple hydrothermal route followed by calcination. The structures and morphologies of the as-synthesized products were characterized by X-ray diffraction, scanning electron microscopy, and Brunauer-Emmett-Teller (BET) surface area analysis, and the results showed that they were uniformly distributed on the Ni foam support. The surface chemical states of the elements in the samples were identified by X-ray photoelectron spectroscopy. The as-synthesized NiCo₂O₄ products were then tested as cathode materials for supercapacitors in a traditional three-electrode system. The electrochemical performances of the NiCo₂O₄ electrode materials were studied and the area capacitance was found to be 1.26 C·cm^-2 at a current density of 1 mA·cm^-2. Furthermore, outstanding cycling stability with 97.6% retention of the initial discharge capacitance after 10000 cycles and excellent rate performance (67.5% capacitance retention with the current density from 1 to 14 mA·cm^-2) were achieved. It was found that the Ni foam supporting the NiCo₂O₄ nanosheets increased the conductivity of the electrode materials. However, it is worth noting that the contribution of nickel foam to the areal capacitance of the electrode materials was almost zero during the charge and discharge processes. To further investigate the practical application of the as-synthesized NiCo₂O₄ nanosheets-based electrode, a device was assembled with the as-prepared samples as the positive electrode and active carbon (AC) as the negative electrode. The assembled supercapacitor showed energy densities of 0.14 and 0.09 Wh·cm^-3 at 1.56 and 4.5 W·cm^-3, respectively. Furthermore, it was able to maintain 95% of its initial specific capacitance after 10000 cycles. The excellent electrochemical performance of the NiCo₂O₄ nanosheets could be ascribed to their unique spatial structure composed of interconnected ultrathin nanosheets, which facilitated electron transportation and ion penetration, suggesting their potential applications as electrode materials for high performance supercapacitors. The present synthetic route can be extended to other ternary transition metal oxides/sulfides for future energy storage devices and systems.     

Facile synthesis of high electrical conductive CoP via solid-state synthetic routes for supercapacitors

Co-P precursor was prepared by a mechanical alloying method and then is controlled to synthesis of Co P phase through an annealing method. The optimal conditions of ball milling and annealing temperature are investigated. The Co P exhibits higher electrical conductivity than graphite and cobalt oxide, showing excellent pseudocapacitive properties due its high electrical conductivity which can result in a fast electron transfer in high rate charge–discharge possess. The as-obtained Co P electrode achieves a high specific capacitance of 447.5 F/g at 1 A/g, and displays an excellent rate capability as well as good cycling stability. Besides, the asymmetric supercapacitor(ASC) based on the Co P as the positive electrode and activated carbon(AC) as the negative electrode was assembled and displayed a high rate capability(60%of the capacitance is retained when the current density increased from 1 A/g to 12 A/g), excellent cycling stability(96.7% of the initial capacitance is retained after 5000 cycles), and a superior specific energy of19 Wh/kg at a power density of 350.8 W/kg. The results suggest that the Co P electrode materials have a great potential for developing high-performance electrochemical energy storage devices.     

MoO2/C共包覆Si/石墨复合锂离子电池负极材料的研究

采用溶胶-凝胶法, 用二氧化钼(MoO₂)和C共同包覆Si/石墨粒子制备了Si/石墨/MoO₂/C锂离子电池负极材料. 利用X射线衍射(XRD)、 扫描电子显微镜(SEM)、 透射电子显微镜(TEM)、 循环伏安(CV)和电化学阻抗(EIS)等分析了材料的形貌和性质. 结果表明, MoO₂/C的共包覆在缓解材料体积膨胀的同时提高了材料的电子和离子电导率, 进而提高了材料的电化学性能. 复合材料的首次充电比容量为2494 mA·h/g, 首次库仑效率为72%, 经过100次循环后比容量为636.6 mA·h/g.