Preparation of Eco-Friendly High-Performance Manganese Dioxide Supercapacitors by Linear Sweep Voltammetry

In this paper,the non-polluting,non-toxic,and eco-friendly material-MnO_(2)electrodes were deposited on three-dimensional porous nickel(Ni)foam by linear sweep voltammetry,and the entire electrodeposition process did not require sintering of the material,which was fast and convenient while avoiding unnecessary energy consump-tion and thus was environmentally friendly.Scanning electron microscopy(SEM)and transmission electron microscopy were used to examine the surface and microscopic characteristics of each sample(TEM).Chronoam-perometry(CA),cyclic voltammetry(CV),galvanostatic charge/discharge(GCD),and electrochemical impedance spectroscopy(EIS)were then used to determine the electrochemical characteristics of the manufactured samples.The result suggests that the MnO_(2)-sv80 electrode sample at a scan rate of 80 mV/s^(−1)has excellent performance for the supercapacitor electrode.The specific capacitance was as high as 531.4 F g^(−1)at a current density of 1 A g^(−1)and remained at 223.2 F g^(−1)at an ultra-high current density of 20 A g^(−1),with capacitance retention of 42%.

一步法制备TiO2/石墨烯复合多孔薄膜应用于增强光催化活性及光伏性能

纳米二氧化钛具有制备简单、成本低、化学稳定性好及光响应度高等诸多优势,因而广泛应用于光催化及太阳能转化等诸多领域中.然而,传统TiO2纳米材料受限于较高光电子空穴复合率,导致其光催化活性及光电转化效率较低.为解决这一问题,研究者采用多种方法用以改善纳米TiO2的结构,包括化学掺杂、半导体材料插层、碳材料杂化等;另一方面则关注材料结构的设计,例如将合成的纳米材料进一步加工为多孔薄膜,以增大材料比表面积及器件稳定性,以增强其器件性能.其中,将石墨烯引入纳米TiO2中,形成复合纳米材料,以提升材料本身的光电子传输效率,降低光生载流子复合率,为制备高性能光催化剂及光伏器件开辟了一条可行之路.然而,目前制备的纳米TiO2/石墨烯复合材料的性能仍不理想,其中常见的问题为合成的材料团聚严重,导致光生载流子在界面传输阻力及复合率都十分高,限制其实际应用.此外,当前大多数关于纳米TiO2/石墨烯的制备方法仍为溶胶凝胶法、水热法等,所得材料需要进一步进行微纳加工方能形成介孔结构;这些加工方式往往需要二次退火处理,这会进一步加重纳米材料的团聚现象,导致孔隙率分布混乱、材料界面缺陷增多等不良结果.因此,本文采用一步法-蒸汽热法成功制备了TiO2/石墨烯复合多孔薄膜,无需二次热处理.实验结果表明,所制TiO2/石墨烯复合物(VTH)的形貌为二维结构,其比表面积高达260 m^2g^-1,获得的多孔薄膜无明显团聚且孔隙分布集中.当复合物中还原氧化石墨烯含量为5.0wt%时,其光催化活性最高,高于单一的TiO2薄膜近3倍;将还原氧化石墨烯含量为0.75wt%的复合物用于染料敏化太阳能电池的光阳极时,光电转化效率达到7.58%,明显高于传统方法制备的单一TiO2的(4.38%).