General synthesis of hollow mesoporous conducting polymers by dual-colloid interface co-assembly for high-energy-density micro-supercapacitors

Rational design and precise regulation over the morphology, structure, and pore size of functional conducting mesoporous polymers with enriched active sites and shorten electron–ion transport pathway are extremely important for developing high-performance micro-supercapacitors (MSCs), but still remain a great challenge. Herein, a general dual-colloid interface co-assembly strategy is proposed to fabricate hollow mesoporous polypyrrole nano-bowls (mPPy-nbs) for high-energy-density solid-state planar MSCs. By simply adjusting the size of block copolymer micelles, the diameter of polystyrene nanospheres and the amount of pyrrole monomer, mesopore size of the shell, void and shell thickness of mPPy-nbs can be simultaneously controlled. Importantly, this strategy can be further utilized to synthesize other hollow mesoporous polymers, including poly(tris(4-aminophenyl)amine), poly(1,3,5-triaminobenzene) and their copolymers, demonstrative of excellent universality. The structurally optimized mPPy-nb exhibits high specific surface area of 122 m^(2) g^(−1)and large capacitance of 225 F g^(−1) at 1 mV s^(−1). Furthermore, the MSCs assembled by mPPy-nbs deliver impressive volumetric capacitance of 90 F cm^(−3) and energy density of 2.0 mWh cm^(−3), superior to the most reported polymers-based MSCs. Also, the fabricated MSCs present excellent flexibility with almost no capacitance decay under varying bending states, and robust serial/parallel self-integration for boosting voltage and capacitance output. Therefore, this work will inspire the new design of mesoporous conducting polymer materials toward high-performance microscale supercapacitive devices.

高比表面积碳纳米碗在超级电容器中的应用

以间苯二酚和甲醛作为碳源,利用模板微球塌陷成碗状结构制备碳纳米碗,再以氢氧化钾作为活化剂高温下活化以获得高比表面积。采用扫描电镜、拉曼散射、氮气吸附脱附、循环伏安、恒流充放电及电化学交流阻抗等方法对其性能进行测试。结果表明,活化碳纳米碗的比表面积高达1423m2/g,在充放电电流密度为0.5A/g的条件下,比电容为175F/g,循环3000次(20A/g)以后可保持96.8%的电容量,实验结果表明是一种优良的超级电容器电极材料。

NiO纳米碗状阵列的低压电阻开关特性

我们利用单层胶体球自组装模板结合电化学沉积和磁控溅射方法在覆盖Pt导电层的白云母衬底上制备了NiO纳米碗状阵列(Nano-bowl-like NiO Array,nb-NiO).每个NiO纳米碗高约450 nm,碗口直径约450 nm,碗深约300 nm,在Pt导电层上密排形成二维阵列.在nb-NiO阵列上覆盖厚约20 nm的HfO_(2)薄膜,然后制备Ag或Pt点电极形成Ag(Pt)/HfO_(2)/nb-NiO/Pt堆栈器件.器件在小于±0.4 V的翻转电压下即可在高低电阻态之间周期性可逆跳变,表现出良好的电阻开关特性:器件在高低电阻态之间翻转的时间<8.7μs;初始高/低电阻比值~10^(4),连续测试1500个周期后依然>10^(3).断电后,器件稳定在高(低)电阻态的时间>104s.纳米碗状阵列结构使得NiO薄膜厚度在150–450 nm内周期性连续变化;由于氧空位导电细丝更易在厚度较小的纳米碗底部导通,因此碗状阵列结构使得原本空间随机分布的氧空位导电细丝通道具有了局域有序性,进而提升了器件电阻开关性能的稳定性.HfO_(2)薄膜层降低了器件漏电流,提高了器件的高/低电阻值比.Ag电极与氧离子的氧化还原反应加速了氧空位导电细丝的导通和断裂,从而降低了翻转电压.

图纹结构Co/Pt多层膜的制备及垂直磁各向异性研究

采用自组装技术制备大面积有序聚苯乙烯微球模板.在此基础上,制备Co/Pt多层膜纳米碗列阵阵列.利用扫描电子显微镜(SEM)和振动样品磁强计(VSM)对样品表面形貌和磁性进行了分析.结果表明:纳米碗阵列保留了聚苯乙烯微球模板的有序形貌.磁性多层膜随着Pt或Co厚度的增大,矫顽力和Mr/Ms变化的总体趋势是先增大后减小.随着衬底胶体球半径的增加,曲率诱导作用逐渐减弱,矫顽力降低.

自组装单层和多层衬底制备纳米碗的对比研究

采用不同自组装技术制备单层和多层有序聚苯乙烯微球模板.在此基础上,制备Co/Pt多层膜纳米碗阵列.利用扫描电子显微镜(SEM)、透射电子显微镜(TEM)和振动样品磁强计(VSM)对两种样品表面形貌和磁性进行了分析.结果表明:以单层和多层模板制备磁性多层膜纳米碗结构,在不考虑纳米点的相同条件下,只要微球直径相同,其制备的纳米碗Co/Pt多层膜磁性相同.

图纹结构Co/Pt多层膜的制备及研究

先采用自组装技术制备大面积有序聚苯乙烯微球模板,在此基础上,制备Co/Pt多层膜纳米碗和纳米点列阵样品.利用扫描电子显微镜(SEM)、原子力显微镜(AFM)和透射电子显微镜(TEM)对制备样品的表面形貌进行了分析.结果表明:溅射方法和刻蚀处理对纳米碗和纳米点的形貌存在影响,磁滞回线的结果表明倾斜溅射条件下制备的纳米点阵具有明显的方向取向性.

新型大孔径TiO2纳米碗状阵列的制备及其机制

用两步阳极氧化法简便快捷地制备出低成本TiO2纳米碗阵列。固定阳极氧化电压、实验温度和电解液浓度等因素、改变第二次阳极氧化时间并结合扫描电镜等测试手段考察阵列碗状结构的形成过程,从阵列的形成机制研究了TiO2纳米碗内TiO2阻挡层的纵向生长、电解液的溶解、纵向腐蚀及横向扩展之间关系的变化。结果表明,当纵向生长与纵向溶解、纵向腐蚀与横向扩展达到平衡时,TiO2碗内纳米孔消失,孔径与碗口直径相同。当第二次阳极氧化时间为110 s时,合成出133 nm的TiO2纳米碗状阵列。