石墨烯与复合纳米结构SiO_2@Au对染料敏化太阳能电池性能的协同优化

染料敏化太阳能电池(dye-sensitized solar cells, DSCs)因其制备工艺简单、成本低廉以及优异的光学性质在近年来引起了大家的广泛关注.为了获得更优的光电性能,利用球磨法制备了一系列不同含量纳米结构SiO_2@Au和固定含量石墨烯协同掺杂的复合光阳极薄膜,并制备了相应的DSCs.研究了纳米结构SiO_2@Au和石墨烯联合掺杂对光阳极及其相应DSCs光电转换性能的影响.金纳米颗粒因其局域表面等离子体共振效应能够有效提高DSCs的短路电流密度.而石墨烯作为典型的二维材料,具有较大的比表面积以及高导电性等优异性质,有利于增加薄膜的比表面积.当纳米结构SiO_2@Au和石墨烯协同掺杂至光阳极薄膜内部,且SiO_2@Au掺杂量为1.5%时,相应电池的短路电流密度为15.59 m A·cm–2,光电转换效率为6.68%,相比基于传统纯TiO_2光阳极电池的性能分别提高了15.67%和8.8%.研究表明,基于不同含量复合纳米结构SiO_2@Au和固定量石墨烯共掺的DSCs性能的提高,主要归因于复合纳米结构SiO_2@Au的掺入,其中分布较为均匀的金纳米颗粒作为光学天线可以将光局域到颗粒表面,增强表面电磁场强度,有效增强光与物质的相互作用,优化了染料的光吸收能力,增加薄膜内部光生载流子数量.而石墨烯的引入则改善了光阳极薄膜的比表面积,增加了薄膜整体对染料的吸附量,且石墨烯良好的导电性能加快了光生载流子的传输,两者协同作用实现了DSCs的光电转换性能的优化.     

Co_2SnO_4/Graphene复合材料的制备与电化学性能研究

实验首先采用改进的Hummers法制备氧化石墨,然后以氧化石墨烯为前驱体,通过水热法将锡酸钴纳米颗粒均匀镶嵌在石墨烯薄膜基片上,最终获得Co2SnO4/Graphene镶嵌复合材料.采用X射线衍射(XRD)、扫描电子显微镜(SEM)对材料的结构和形貌进行表征,通过恒电流充放电(CC)、循环伏安法(CV)与交流阻抗法(EIS)测试了材料的电化学性能.实验结果表明,石墨烯良好的分散性及较高的电子导电率,可以提高锡酸钴材料的电化学性能,材料首次可逆容量达到1415.2 mA·h/g,50次循环后仍能保持469.7 mA·h/g的放电比容量.     

锂离子电池Sn-Al薄膜电极的制备及电化学性能研究

采用磁控溅射沉积技术制备了纳米级Sn-Al合金薄膜电极材料,并用X射线衍射和扫描电子显微镜进行表征,用高精度电池测试系统进行充放电和循环伏安测试.结果表明直流DC与射频RF两种不同的溅射方法制备的Sn-Al薄膜电极具有很大的性能差异,前者DC法制备的材料颗粒细小,表现出稳定的循环性能,其首次放电容量为1060 mAh/g,首次效率为71.7％,电极经过50次循环后比容量保持在700 mAh/g以上.后者RF法制备的材料颗粒较大,放电比容量开始上升,第五次循环后接着逐渐衰减,表现出较差的循环性能. 关键词： 锂离子电池 磁控溅射 Sn-Al合金 电化学性能     

基于石墨烯/PEDOT：PSS叠层薄膜的柔性OLED器件

石墨烯具有独特的电学性能、优异的机械延展性和良好的化学稳定性,是制备高性能导电薄膜的理想材料,但是当前石墨烯的高电阻率限制了它的实际应用。本文采用喷涂方法制备了石墨烯/聚（3,4-亚乙二氧基噻吩）-聚（苯乙烯磺酸）（PEDOT：PSS）复合导电薄膜,对复合薄膜的表面形貌与光电性能进行了研究。PEDOT：PSS的引入不仅降低了石墨烯薄膜的表面电阻,同时还平滑了薄膜表面。在此基础上,成功制备了柔性黄光有机电致发光器件,器件在12 V时达到效率最大值0.9 cd/A。器件在曲率半径为10 mm时弯曲了100次后,发光亮度并无明显变化。该复合薄膜可实际应用于柔性有机电致发光显示器件。     

Co$lt;sub$gt;2$lt;/sub$gt;SnO$lt;sub$gt;4$lt;/sub$gt;/Graphene复合材料的制备与电化学性能研究

实验首先采用改进的Hummers法制备氧化石墨,然后以氧化石墨烯为前驱体,通过水热法将锡酸钴纳米颗粒均匀镶嵌在石墨烯薄膜基片上,最终获得Co₂SnO₄/Graphene镶嵌复合材料. 采用X射线衍射（XRD）、扫描电子显微镜（SEM）对材料的结构和形貌进行表征,通过恒电流充放电（CC）、循环伏安法（CV）与交流阻抗法（EIS）测试了材料的电化学性能. 实验结果表明,石墨烯良好的分散性及较高的电子导电率,可以提高锡酸钴材料的电化学性能,材料首次可逆容量达到1415.2 mA·h/g,50次循环后仍能保持469.7 mA·h/g的放电比容量. 关键词： 2SnO₄')" href="#">Co₂SnO₄ 石墨烯 电化学性能 锂离子电池     

电化学阴极沉积制备氧化镍/碳纳米管复合电极的准电容特性

采用催化裂解的方法制备了碳纳米管,其比容量为12F/g.采用碳纳米管作为电极基体,采用阴极电化学还原Ni(NO3)2的方法在碳纳米管基体表面均匀的沉积了纳米氧化镍颗粒并由此制备了氧化镍碳纳米管复合电极材料.采用循环伏安、恒流充放电、交流阻抗及扫描电镜等方法考察了复合电极材料的容量特性、阻抗特性、自放电特性以及电极表观特征.实验表明复合电极具有良好的电化学特性,碳纳米管基体在明显降低氧化镍材料的阻抗的同时还提高了电极材料的电化学容量并拓宽了电极材料的有效工作电位窗,复合电极在6mol/LKOH电解液中比容量达到25F/g且表现了良好的电化学可逆性.与碳纳米管基电容器相比,采用氧化镍复合电极材料组装的电容器具有较低的自放电率.     

电化学阴极沉积制备氧化钴/CNTs复合电极的准电容特性

采用电化学阴极沉积还原Co(NO3)2的方法制备了具有准电容特性的氧化钴电极材料,其比容量达到280 F／g,采用CNTs作为电极基体,在其表面均匀的沉积了纳米钴化镍颗粒并由此制备了氧化钴碳纳米管复合电极材料.采用循环伏安,恒流充放电,交流阻抗及扫描电镜等方法考察了复合电极材料的容量特性、阻抗特性、自放电特性以及电极表观特征．实验表明复合电极具有良好的电化学特性,CNTs基体在明显降低氧化镍材料的阻抗的同时还提高了电极材料的电化学容量并拓宽了电极材料的有效工作电位窗,复合电极在1 mol／L KOH电解液中比容量达到322 F／g且表现了良好的电化学可逆性．并分别采用氧化钴／CNTs复合电极作为正极,活性炭纤维作为负极制备了复合型电化学电容器,其工作电压达到1．4 V,电容器质量比容量达到47 F／g．在0．1 A／cm2放电时,复合型电容器的能量密度达到10 Wh／kg,兼具高能量特性和优良的大电流放电特性．     

旋涂法酸处理PEDOT∶PSS薄膜对OLED性能的影响

采用旋涂法对PEDOT∶PSS薄膜进行了酸处理,研究了不同方法处理PEDOT∶PSS薄膜对器件ITO/酸处理PEDOT∶PSS/NPB/Alq3/Li F/Al性能的影响。实验结果表明:用盐酸(草酸)处理PEDOT∶PSS薄膜时,以0.75 mol/L的盐酸(草酸)在120℃下退火15 min时性能更好,最大电流效率达到4.28 cd/A。并且盐酸、草酸处理PEDOT∶PSS薄膜制备器件比未处理PEDOT∶PSS薄膜制备器件的电流效率明显提高了34%。     

电化学制备钛网负载聚吡咯/石墨烯复合膜及其在超级电容器中的应用

通过电化学的方法在钛网上制备了聚吡咯与石墨烯的复合物薄膜,其过程是先在钛网上通过自组装干燥膜法附着上石墨烯氧化物膜,而后采用电化学还原的方法原位还原制备得到石墨烯膜,随后加入吡咯单体,再通过电化学聚合的方法在石墨烯的表面生长聚吡咯,得到的聚吡咯开始以颗粒的形式存在,而后随着聚合的进行得到了链状的聚吡咯.得到的复合膜有高的比表面积和导电性,可以作为电极活性材料用于超级电容器中提供赝电容,结果表明,复合膜作为电极材料的超级电容器拥有高的性能,比电容达400 F/g,并且电极的充放电稳定性高,5000次复合膜充放电循环后比电容还能保留82%,说明该材料适合于超级电容器.     

溶胶凝胶方法制备纳米氧化钌的超电容特性

采用溶胶凝胶方法制备了具有纳米尺度和多孔特征的氧化钌超电容器活性材料,探讨了烧结温度对电极材料的晶体结构,颗粒大小及电化学特性的影响．结合热失重分析、扫描电镜、循环伏安测试等方法探讨了溶胶凝胶法制备钌产物的组成及在高温条件下发生的分解过程和相应产物．钌氧化物材料经过210℃烧结处理后具有541 F／g的电化学容量,由其组成的超电容器具有67 J/g的能量密度．采用高导电乙炔黑作为载体制备了氧化钌／乙炔黑复合电极材料,当乙炔黑含量为10％时,电极材料的比容量达到802 F/g,采用该电极材料组成的电化学电容器具有100 J／g的能量密度且表现了良好的高功率放电特性．     

Synthesis of aqueous dispersion of graphenes via reduction of graphite oxide in the solution of conductive polymer

Graphene sheets were produced by chemical reduction of graphite oxides in the solution of ionic conductive polymer, Nafion. The obtained graphene, coated with Nafion, can be re-dispersed in water, and readily forms stable dispersed state. The polymer-coated graphene had been characterized by FT-IR spectroscopy, UV-vis and X-ray photoelectron spectroscopy (XPS). The PEDOT film with Nafion-coated graphene increased significantly from 0.25 S/cm for pure PEDOT film and reached 12 S/cm. Further, the films of PEDOT doped Nafion-coated graphene had also higher conductivities compared to films doped PSS-coated graphene.     

Conductivity of Composite Films Based on Conductive Polymer PEDOT:PSS,Graphene Oxide and Nanoparticles TiO2 for Contact Layers of Perovskite Photovoltaic Structures

Physics of the Solid State - The electrical properties of composite films based on conductive polymer PEDOT: PSS, graphene oxide (GO), and titanium dioxide nanoparticles (TiO2) (PEDOT: PSS–...     

Reduced graphene oxide/MWCNT hybrid sandwiched film by self-assembly for high performance supercapacitor electrodes

A reduced graphene oxide/multiwalled carbon nanotube (RGO/MWCNT) hybrid sandwiched film with different MWCNTs content was prepared by vacuum-assisted self-assembly from a complex dispersion of graphene oxide (GO) and MWCNTs followed by heat-treating at 200 °C for 1 h in a vacuum oven to reduce the GO into RGO. The free-standing RGO/MWCNT hybrid sandwiched film before heat-treatment showed a layered structure with an entangled network of MWCNTs sandwiched between the GO sheets. This unique structure not merely contribute to remove the oxygen-containing groups in GO during the heat-treatment, but also decrease the defects for electron transfer between RGO layers, which enhances the electrochemical capacitive performances of graphene-based films. A specific capacitance up to 379 F/g was achieved based on RGO/MWCNT with 30 % MWCNTs mass fraction at 0.1 A/g in a 6 M KOH electrolyte. The excellent performance of RGO/MWCNT hybrid sandwiched film signifies the importance of controlling the surface chemistry and sandwiched nanostructure of graphene-based materials.     

Nanocomposite of p-type conductive polymer/Cu (II)-based metal-organic frameworks as a novel and hybrid electrode material for highly capacitive pseudocapacitors

In this paper firstly, Cu (II)-based metal-organic framework (MOF; Cu-bipy-BTC, bipy = 2,2′-bipyridine, BTC = 1,3,5-tricarboxylate) was synthesized using chemical approach and then fabricated hybrid poly ortho aminophenol (POAP)/Cu-bipy-BTC films by electropolymerization of POAP in the presence of Cu-bipy-BTC nanoparticles to serve as the active electrode for electrochemical storage device. Surface analysis and electrochemical analysis have been used for characterization of POAP/Cu-bipy-BTC composite film. Different electrochemical methods including galvanostatic charge–discharge experiments, cyclic voltammetry, and electrochemical impedance spectroscopy are carried out in order to investigate the performance of the system. This work introduces new nanocomposite materials for electrochemical redox capacitors with advantages including ease synthesis, high active surface area, and stability in an aqueous electrolyte.     

Enhanced thermoelectric properties of PEDOT/PSS/Te composite films treated with H<Subscript>2</Subscript>SO<Subscript>4</Subscript>

Firstly, tellurium (Te) nanorods with a high Seebeck coefficient have been integrated into a conducting polymer PEDOT/PSS to form PEDOT/PSS/Te composite films. The Seebeck coefficient of the PEDOT/PSS/Te (90 wt.%) composite films is ~191 μV/K, which is about 13 times greater than that of pristine PEDOT/PSS. Then, H₂SO₄ treatment has been used to further tune the thermoelectric properties of the composite films by adjusting the doping level and increasing the carrier concentration. After the acid treatment, the electrical conductivity of the composite films has increased from 0.22 to 1613 S/cm due to the removal of insulating PSS and the structural rearrangement of PEDOT. An optimized power factor of 42.1 μW/mK² has been obtained at room temperature for a PEDOT/PSS/Te (80 wt.%) sample, which is about ten times larger than that of the untreated PEDOT/PSS/Te composite film.     

Capacitance properties of poly(3,4-ethylenedioxythiophene)/carbon nanotubes composites

The electrochemical properties of composites prepared from an electrically conducting polymer poly(3,4-ethylenedioxythiophene), i.e. PEDOT and multiwalled carbon nanotubes (CNTs) have been investigated for supercapacitor application. The novel composite material was prepared by chemical or electrochemical polymerization of EDOT directly on the nanotubes or from a homogenous mixture of PEDOT and CNTs. Acetylene black (AB) has been also used as a composite component in order to evaluate whether nanotubes are giving improved properties or not. Electrodes prepared from such composites were used in supercapacitors operating in acidic (1 M H₂SO₄), alkaline (6M KOH) and organic (1 M TEABF₄ in AN) electrolytic solutions. The capacitance values were estimated by galvanostatic, voltammetry and impedance spectroscopy techniques with two- or three-electrode cell configuration. Due to the open mesoporous network of nanotubes, the easily accessible electrode/electrolyte interface allows quick charge propagation in the composite material and an efficient reversible storage of energy in PEDOT during subsequent charging/discharging cycles. The composites with AB supply quite good capacitance results, however, nanotubes as electrode component gave definitively a more homogenous dispersion of PEDOT that should give a better charge propagation. The values of capacitance for PEDOT/carbon composites ranged from 60 to 160 F/g and such material has a good cycling performance with a high stability in all the electrolytes. Organic medium is especially interesting because of higher energy stored. Another quite important advantage of this composite is its significant volumetric energy because of the high density of PEDOT.     

减反膜的梯度化与激光损伤阈值之间的关系研究

光学减反膜是激光系统的重要组成部分，也是在激光照射下最容易发生损伤的部分，如何提高减反膜的激光损伤阈值是研究的热点之一。在保持目标透射光谱要求和膜系总光学厚度不变的前提下，研究了不同梯度化减反膜与激光损伤阈值之间的关系。首先采用混合渐变膜系设计方法设计了一种渐变减反膜系，G/H₁→H/L/A；其次通过渐变折射率分层等效方法将渐变减反膜系进行不同的梯度化，并利用PECVD技术，在K9玻璃上沉积了满足光学性能指标要求的不同渐变减反膜系(多层梯度渐变膜系和相应的坡度渐变膜系)；最后进行了激光损伤阈值(LIDT)测量。研究结果表明:在保持目标透射光谱要求和膜系总光学厚度不变的前提下，渐变减反膜系相比于传统减反膜系，抗激光损伤阈值有明显的提高；随着梯度化层数的增加，渐变减反膜系的激光损伤阈值呈减小的趋势；对于相同膜层的渐变折射率薄膜，采用坡度法制备的样片抗激光损伤阈值均优于采用梯度化制备的样片。     

ps-laser scribing of CIGS films at different wavelengths

Continuous growth of the thin-film electronics market stimulates the development of versatile technologies for large-scale patterning of thin-film materials on rigid and flexible substrates, and laser technologies are a promising method to accomplish the scribing processes. Lasers with picosecond pulse duration were applied in scribing of complex multilayered CuIn _x Ga_(1−x)Se₂ (CIGS) solar cells deposited on a polyimide substrate. The ablative properties of the films were examined as a function of the wavelength of laser radiation, pulse energy, and the irradiation dose. The selective removal of ITO and CIGS layers was achieved with 355 nm irradiation without any significant damage to the underlying layers in the ITO/CIGS/Mo/PI solar cell system. The 355 nm wavelength was also found to be favorable for scribing of absorber layer in a ZnO/CIGS/Mo/PI solar cell system. 266 nm radiation significantly modified the film structure due to high absorption. Extensive melt formation in the CIGS layer was found when 532 nm radiation was applied, though the trenches were smooth and crack-free.