聚吡咯/还原氧化石墨烯复合物的合成及电容性能

通过原位聚合方法制备不同配比的聚吡咯/氧化石墨（PPy/GO）复合物,将其用NaBH4还原得到聚吡咯/还原氧化石墨烯(PPy/RGO)复合物,采用X射线衍射、红外光谱和场发射扫描电子显微镜（FESEM）对其结构和形貌进行物理表征。 采用循环伏安、恒电流充放电和交流阻抗等电化学方法系统研究了所制备样品的电化学性能。 实验结果表明,在电流密度为0.5 A/g、吡咯（Py）与GO质量比为95∶5时,得到的复合物还原前后比电容分别可达401.5和314.5 F/g,远高于单纯的GO（34.8 F/g）和PPy（267.5 F/g）。 经过1200圈循环稳定性测试后,PPy/RGO复合物比电容保持了原来的62.5%,与PPy和PPy/GO（电容保持率分别为16.8%和46.4%）相比,PPy/RGO表现出更好的循环稳定性能,有望成为超级电容器电极材料。     

“化学一步法”制备电磁功能化聚吡咯/γ-Fe2O3复合物纳米球及结构表征

在不添加掺杂剂的条件下, 以吡咯为单体, 三氯化铁为氧化剂, 采用"化学一步法"合成了电磁功能化的聚吡咯/γ-Fe2O3 复合物纳米结构. 研究了不同氯化亚铁用量对聚吡咯/γ-Fe2O3 复合物形貌、 电学性能以及磁学性能的影响. 结果表明, 氯化亚铁的用量对聚吡咯/γ-Fe2O3复合物的形貌影响不大, 都得到了聚吡咯/γ-Fe2O3复合物纳米球; 然而, 聚吡咯/γ-Fe2O3复合物纳米球的电学和磁学性能却明显受到氯化亚铁用量的影响. 聚吡咯/γ-Fe2O3复合物纳米球的电导率和最大饱和磁化强度随着氯化亚铁用量的增加而增大, 并在氯化亚铁用量增加到150 mg时达到最大值, 分别为72.1 S/cm和10.07 A·m2/kg, 实现了高电学性能和高磁学性能兼顾的电磁功能化导电聚合物纳米结构的制备.     

石墨烯量子点增强聚吡咯超级电容器电极的电化学性质(英文)

通过将吡咯单体在低温下与石墨烯量子点进行原位聚合,获得一种全新的聚吡咯/石墨烯量子点(PPY/GQD)复合材料.实验中采用了扫描电子显微镜(SEM)、原子力显微镜(AFM)、X射线衍射(XRD)、红外光谱(FT-IR)和热重分析(TGA)对复合物的表面形貌、结构进行表征.结果表明,吡咯单体以石墨烯量子点为软模板,以化学键的方式在石墨烯量子点的表面聚合生长成片状聚吡咯.通过机械冷压法将粉末状PPY/GQD复合物压成圆片电极.电极的电化学测试结果表明,PPY和GQD质量比为50:1所制得的复合物的电容量为485 F.g-1,同时在2000次循环之后电容量只降低了大约2%.通过与同比例的PG(聚吡咯/石墨烯复合材料)以及纯PPY对比,发现聚吡咯/石墨烯量子点的高比容量及优异的循环稳定性将会使其在电化学超级电容器领域中具有潜在的应用价值.     

交联多孔结构的Mn2 掺杂聚苯胺/石墨烯复合材料的制备及超级电容特性

采用简单的原位氧化聚合法成功制备了Mn₂ 掺杂聚苯胺/石墨烯(Mn₂ -PANI/rGO)复合物电极材料,利用傅里叶变换红外(FT-IR)光谱、X射线衍射(XRD)、扫描电镜(FESEM)和电化学测试等手段对其结构、形貌和电化学电容性能进行了分析研究。结果表明,纳米棒状的锰离子掺杂态聚苯胺均匀分散在褶皱的石墨烯中,形成交联状的多孔结构;Mn₂ -PANI/rGO复合物具有高的比电容和优良的循环稳定性,当电流密度为2A/g时,电极的放电比容量高达952 F/g, 循环1000 次后初始比电容的保持率为86.2%,这表明过渡金属和石墨烯的加入增强了其电化学性能,高的比电容和好的速率使其复合物有望在超级电容器中有广泛的应用前景。     

壳层可控导电聚吡咯/聚苯乙烯复合微球及聚吡咯中空微胶囊的制备

在导电聚合物含量较小时,含核壳结构的导电聚合物复合粒子就可以具有和本体相当的导电率,且加工性好,近年来这种核壳结构微粒的制备已引起了科学家们的广泛关注．Armes等[制备了导电聚吡咯、导电聚苯胺包覆聚苯乙烯的核壳结构胶体粒子及聚苯胺和二氧化硅的纳米复合物．刘正平等用改进的方法在粒径为116nm的单分散聚苯乙烯乳胶粒子上包覆聚吡咯,     

聚吡咯/氧化石墨烯层状复合材料的制备及其在超级电容器中的应用(英文)

通过将吡咯单体在低温下与氧化石墨烯进行原位聚合,获得聚吡咯/石墨烯(Ppy/CRGO)复合材料.采用场发射电子显微镜(FESEM)、红外(FT-IR)和热重分析(TGA)对复合物的表面形貌、结构进行表征.FESEM结果表明,通过控制氧化石墨烯(GO)和吡咯单体的质量比例,可以对复合物的层状和厚度进行调控.FT-IR和TGA结果表明,聚吡咯(Ppy)是通过化学键合的方式与氧化石墨烯复合在一起.通过机械冷压法将粉末状Ppy/CRGO复合物压成圆片电极,并探讨了石墨烯和聚吡咯复合比例、反应时间、烘干温度和孔隙率等因素对Ppy/CRGO复合物电极的电学和电化学性能的影响.结果表明,Ppy与CRGO质量比为10∶1所制得的Ppy/CRGO复合物的电容量为421 F·g-1,通过在电极中引入孔隙,电容量能进一步提升为509 F·g-1.     

聚吡咯/海藻酸钠纳米球的制备及其应用于高性能超级电容器

用海藻酸钠作为结构导向剂,通过原位氧化聚合吡咯法制备了聚吡咯/海藻酸钠(PPy/SA)纳米球.聚吡咯/海藻酸钠纳米球的形貌和结构通过扫描电镜(SEM)、X射线衍射(XRD)和傅里叶变换红外(FTIR)光谱进行表征.材料的电化学性能通过循环伏安法和恒电流充放电方法进行测试.电化学测试表明,聚吡咯/海藻酸钠纳米球在1 mol L-1KCl电解液中,电流密度为1 A g-1时其比电容高达347 F g-1.与纯聚吡咯相比较,聚吡咯/海藻酸钠纳米球具有更优异的循环稳定性能.     

氢键诱导的聚吡咯/苯磺酸功能化多壁碳纳米管的制备及其电化学行为

采用原位芳基重氮化反应对碳纳米管进行苯磺酸功能化, 进而制备了聚吡咯/苯磺酸化碳纳米管复合材料(PPy/f-MWCNTs), 通过透射电镜(TEM)及扫描电镜(SEM)测试发现, 氢键诱导使聚吡咯成功地包覆在碳纳米管表面. 循环伏安和恒流充放电测试结果表明, 复合材料具有良好的电化学电容性能, 当聚吡咯与苯磺酸化碳纳米管质量比为1:1时, 复合材料在1.0 A·g-1的电流密度下的比容量达266 F·g-1, 而且聚吡咯利用率比未功能化聚吡咯/碳纳米管(PPy/p-MWCNTs)和纯聚吡咯(PPy)提高了1倍以上.     

聚苯胺/聚吡咯-纳米二氧化硅复合薄膜的合成及防腐性能

采用循环伏安法(CV)在316不锈钢(316SS)表面聚合生成聚苯胺/聚吡咯-纳米二氧化硅(PAni/PPySiO_2)共聚复合薄膜.通过电化学工作站、傅里叶变换红外光谱仪(FTIR)、X射线光电子能谱仪(XPS)和扫描电子显微镜(SEM)等考察了聚苯胺(PAni)、聚苯胺/聚吡咯(PAni/PPy)与PAni/PPy-SiO_2薄膜的电化学聚合过程、分子结构和特征形貌;在3.5%(质量分数)Na Cl水溶液中利用Tafel极化曲线和电化学阻抗谱(EIS)分别考察了PAni,PAni/PPy与PAni/PPy-SiO_2薄膜对不锈钢的防腐性能.结果表明,通过电化学法可以在316不锈钢表面生成PAni/PPy-SiO_2共聚复合薄膜;相对于PAni薄膜与PAni/PPy薄膜,PAni/PPy-SiO_2薄膜有着更密实的表面结构,其对不锈钢的保护能力优于PAni/PPy薄膜和PAni薄膜,纳米SiO_2的掺杂通过加强膜层的机械屏蔽作用并抑制腐蚀反应过程中电荷的传递,提高了薄膜的防腐能力.     

镧掺杂锶铁氧体-聚吡咯复合物的制备及磁性研究

用溶胶-凝胶法和溶液原位合成法分别制备镧掺杂锶铁氧体(Sr1－xLaxFe11.5Ni0.5O19, x＝0.0, 0.1, 0.2, 0.3, 0.4)粉末及其吡咯相对质量分数为60%和80%的聚吡咯-铁氧体复合物微粒PPY (Polypyrrole)/Sr0.8La0.2Fe11.5Ni0.5O19. 借助X射线衍射(XRD)、透射电子显微镜(TEM)、扫描电子显微镜(SEM)、红外光谱(FTIR)和振动样品磁强计(VSM)等分析手段表征了铁氧体粉末和复合物微粒的结构、形貌和磁性能. 结果表明, 包覆的聚吡咯外层对复合物微粒的形貌和磁性有一定的影响. 在外加磁场作用下, 复合物的饱和磁化强度MS随吡咯含量的增加而减小, 当吡咯含量等于0%, 60%和80%时, 对应的MS分别为59.4, 18.7和10.3 emu/g.     

氧化剂对磺化石墨烯负载聚苯胺复合材料结构与电化学性能的影响

以磺化石墨烯(sGNS)为基板材料,通过界面聚合方法制备出不同分级结构磺化石墨烯负载聚苯胺(sGNS/PANI)复合材料,并系统研究了氧化剂类型对复合材料的化学组成、形貌结构和超级电容特性的影响.结果显示,过硫酸铵为氧化剂合成的复合材料中PANI的产率和氧化程度最高,其形貌呈现出sGNS垂直生长PANI纳米短棒阵列结构,PANI的共轭程度和结晶性均较高,从而赋予复合材料高的比电容(497.3 Fg-1),以及良好的倍率特性和循环稳定性(2000次循环后比电容仅损失5.7%).当以三氯化铁为氧化剂时,复合材料中PANI的得率很低,并在sGNS表面形成较薄的包覆层,此时复合材料的比电容最低(228.5 Fg-1),但充放电循环性能较好(2000次循环后比电容的保持率为87.4%).当氧化剂为高锰酸钾时,复合材料中PANI以团聚态颗粒无规堆积在sGNS表面,PANI以无定型结构存在,其比电容虽然较高(419.6 F g-1),但其倍率特性和充放电循环性能较差(2000次循环后比电容损失19.9%).     

三维还原氧化石墨烯/聚苯胺复合材料的制备及其超级电容性能

以制备的氧化石墨凝胶和聚苯胺纳米线为原料, 将二者按一定的质量比进行混合超声分散, 再以混合分散液为前驱体采用一步水热法制备得到三维还原氧化石墨烯(RGO)/聚苯胺(PANI) (RGP)复合材料, 采用扫描电镜(SEM), 透射电镜(TEM), X射线衍射(XRD), 傅里叶变换红外(FT-IR)光谱, X射线光电子能谱(XPS)和电化学测试等分析研究了复合材料的形貌、结构和超级电容性能. 结果表明, 复合材料既保持了还原氧化石墨烯的基本形貌, 又能使聚苯胺较好地镶嵌在还原氧化石墨烯的网状结构中; 且当氧化石墨与聚苯胺的质量比为1:1时复合材料在0.5 A·g^-1电流密度下比电容可高达758 F·g^-1, 即使在大电流密度(30 A·g^-1)下其比容量仍高达400 F·g^-1,在1A·g^-1电流密度下循环1000次后比容量保持率为86%, 表现出了良好的倍率性能和循环稳定性, 其超级电容性能远优于单纯的还原氧化石墨烯和聚苯胺, 其优异的超级电容性能可归咎于二者的相互协同作用.     

聚苯胺/聚砜复合材料的制备及其超级电容性能

通过化学聚合法,制备出盐酸掺杂聚苯胺（PANI）,将其与聚砜（PSF）溶液混合,定量滴加到玻碳电极上制得PANI/PSF复合膜电极。 采用扫描电子显微镜、红外光谱以及X射线衍射对其结构和形貌进行表征。 根据循环伏安曲线、恒电流充放电曲线和电化学阻抗,研究了其作为电极的超级电容性能。 结果表明,多孔结构的PANI/PSF复合材料具有良好的电容性能,其比电容可达到497 F/g,并且该超级电容器具有较小的内阻和较好的循环稳定性。     

Preparation of polyaniline‐coated mesoporous carbon and its enhanced electrochemical properties

Polyaniline/MC (mesoporous carbon) composite was synthesized by in situ chemical polymerization method and was used as a new electrode material for supercapacitor. The composite was characterized by N₂ adsorption and scanning electron microscope. The electrochemical capacitance performance of the composite was investigated by cyclic voltammetry (CV) and galvanostatic charge–discharge tests with a three‐electrode system in a 10 wt% H₂SO₄ solution. The polyaniline/MC composite electrode shows much higher specific capacitance than pure MC electrode, which is attributed to the incorporation of polyaniline onto the pore surface of MC. Copyright © 2009 John Wiley & Sons, Ltd.     

9,10-蒽醌-2-磺酸钠盐掺杂对导电聚吡咯电容性能的促进作用

用恒电位法制成以9,10-蒽醌-2-磺酸钠盐(AQS)为掺杂阴离子的导电聚吡咯(PPy)电化学电容器电极材料,并采用循环伏安(CV)、充放电测试、电化学阻抗(EIS)等方法表征电容性质.结果表明,与高氯酸阴离子(ClO4-)掺杂的PPy相比,PPy/AQS电极材料不仅单位质量电容和电极稳定性得到提高,工作电压范围也得以扩大.在1mol·L-1的氯化钾中,工作电压为-0.6至0.6V,扫描速率为50mV·s-1时其单位质量电容达到491F·g-1,比PPy/ClO4-电极材料提高1.5倍.这是由于AQS自身良好的氧化还原活性和AQS掺杂有利于聚吡咯膜形成疏松多孔的纳米及亚微米颗粒结构而导致的.     

The carbon nanotubes-polyaniline composites and their effect on catalytic properties of deposited catalysts

Composites of functionalized single-wall carbon nanotubes and polyaniline are deposited onto electrodes by in situ electrochemical polymerization. Their electrochemical behavior and differential capacitance are studied by cyclic voltammetry, electrochemical impedance spectroscopy, and chronovoltamperometry. The differential capacitance of the composite electrode exceeds that of pure polyaniline film deposited onto electrode, which can be explained by the nanotubes’ loosening effect on the polyaniline structure. The composite-electrode capacitance is as large as 1000 F g⁻¹ or higher. Thus obtained composite films were used as a support for deposited platinum-ruthenium catalyst. The Pt-Ru structure and catalytic properties in the methanol oxidation reaction are studied. It is shown that the specific current of methanol oxidation at Pt-Ru is larger by a factor of 7–15 than those measured when pure polyaniline, pure carbon nanotubes, or standard Vulcan XC-72 carbon black are used as supports. It is found that the catalytic activity is the same for all studied supports, provided the current is reduced to the unit of Pt-Ru true surface area. Thus, the observed large catalytic effect is associated with the structure and high dispersivity of the electrodeposited metals incorporated to the single-wall carbon nanotubes-polyaniline composite.     

Impact of polypyrrole incorporation on nickel oxide@multi walled carbon nanotube composite for application in supercapacitors

In this article we report the synthesis of polypyrrole incorporated nickel oxide multi walled carbon nanotube (NiO@NMWCNT/PPy) composites by thermal reduction protocol for supercapacitor applications. The structural and morphological properties of the composites were confirmed by the aid of X-ray diffraction (XRD), Field-emission scanning electron microscope (FE-SEM) with energy-dispersive X-ray spectroscopy (EDS), X-ray photoelectron spectroscopy (XPS) and Field-emission transmission electron microscopy (FE-TEM) analysis indicating the hexagonal crystal structure of NiO decorated on NMWCNT/Ppy. The electrochemical characteristics of the NiO@MWCNT/PPy composite were analyzed in the presence of 2 M KOH as an electrolyte. The NiO@NMWCNT/PPy nanostructured composite produced a plenty of active sites for ion migration reactions that facilitate the energy storage mechanism. As a proof of concept demonstration, the NiO@NMWCNT/PPy composite was explored as an electrode materials in supercapacitor and exhibited specific capacitance of 395 F g⁻¹ and cyclic stability up to 5000 cycles at 0.5 A g⁻¹. Enhanced performance of composite is attributed to the incorporation of polypyrrole in NiO@NMWCNT. The improved capacitance and cyclic stability demonstrated by the composite indicates the NiO@NMWCNT/PPy to be a promising candidate for supercapacitor applications.     

应用于氧还原电极的新型Co-PAn-C复合催化材料

借鉴美国Los Alamos国家实验室报告的应用于燃料电池氧电极的新型Co-PPy-C (PPy, polypyrrole)复合物催化材料, 提出Co-PAn-C (PAn, polyaniline)复合材料可能对氧的电化学还原也具有催化活性, 并首次制备出Co-PAn-C复合催化材料. 发现Co-PAn-C对氧还原有显著的催化效果, 碱性介质中氧气气氛下, 电极电位为－0.2 V vs. Hg/HgO时电流密度达到128 mA•cm^－2, 性能也比较稳定. 初步研究了Co-PAn-C对ORR (oxygen reduction reaction)的催化机理, 可能是在结构中形成了Co-N活性位置, 影响了氧和反应中间产物在电极上的吸附和脱附过程.     

The preparation and performance of flocculent polyaniline/carbon nanotubes composite electrode material for supercapacitors

Polyaniline (PANI)/carbon nanotubes (CNTs) composite electrode material was prepared by in situ chemical polymerization. The structure and morphology of PANI/CNTs composite are characterized by Fourier infrared spectroscopy, scanning electron microscope, and transmission electron microscopy. It has been found that a flocculent PANI was uniformly deposited on the surface of CNTs. The supercapacitive behaviors of the PANI/CNTs composite materials are investigated with cyclic voltammetry, galvanostatic charge/discharge, impedance, and cycle life measurements. The results show that the PANI/CNTs composite electrodes have higher specific capacitances than CNT electrodes and better stability than the conducting polymers. The capacitance of PANI/CNTs composite electrode is as high as 837.6 F g⁻¹ measured by cyclic voltammetry at 1 mV s⁻¹. Besides, the capacitance retention of coin supercapacitors remained 68.0% after 3,000 cycles.     

Electrochemical Performance of Free-Standing and Flexible Graphene and TiO2 Composites with Different Conductive Polymers as Electrodes for Supercapacitors

The advantage of using composite electrode materials for energy storage is, to a large extent, the synergistic role of their components. Our work focuses on the investigation of the interactions of each phase, exploring the patterns found with the change of materials to provide theoretical or experimental foundations for future study. Here, conductive polymers (CPs), including polyaniline (PANi), polypyrrole (PPy), and polythiophene (PTh), as well as reduced graphene oxide (rGO), and TiO₂ with the different crystalline phases of anatase and rutile were applied to form a series of free-standing and flexible binary or ternary composite electrodes. The electrochemical behaviors of these composite electrodes are presented. The results indicate that the synergistic improvement in electrochemical performance is due to the incorporation of the different components. CPs significantly increase the current density of these composite films and contribute their pseudocapacitance to improve the specific capacitance, but lead to a decline in cycle stability. After introducing TiO₂, both the specific capacitance and the cycle-stability of rGO-TiO₂-CP were synergistically improved. A CP can magnify the pseudocapacitance behavior of any of the TiO₂ crystalline phases, and interactions vary with the specific CP and the specific TiO₂ crystalline phase employed. The synergistic effects of the as-prepared composites were theoretically predicted and explored.