Materials Science and Engineering Program, University of California, Riverside, CA 92521, USA.
Nanotechnology. 2016 Aug 12;27(32):325502. doi: 10.1088/0957-4484/27/32/325502. Epub 2016 Jun 29.
One-dimensional gold/polypyrrole (Au/PPy) nanopeapods were fabricated using a viral template: M13 bacteriophage. The genetically modified filamentous virus displayed gold-binding peptides along its length, allowing selective attachment of gold nanoparticles (Au NPs) under ambient conditions. A PPy shell was electropolymerized on the viral-templated Au NP chains forming nanopeapod structures. The PPy shell morphology and thickness were controlled through electrodeposition potential and time, resulting in an ultra-thin conductive polymer shell of 17.4 ± 3.3 nm. A post-electrodeposition acid treatment was used to modify the electrical properties of these hybrid materials. The electrical resistance of the nanopeapods was monitored at each assembly step. Chemiresistive ammonia (NH3) gas sensors were developed from networks of the hybrid Au/PPy nanostructures. Room temperature sensing performance was evaluated from 5 to 50 ppmv and a mixture of reversible and irreversible chemiresistive behavior was observed. A sensitivity of 0.30%/ppmv was found for NH3 concentrations of 10 ppmv or less, and a lowest detection limit (LDL) of 0.007 ppmv was calculated. Furthermore, acid-treated devices exhibited an enhanced sensitivity of 1.26%/ppmv within the same concentration range and a calculated LDL of 0.005 ppmv.
一维金/聚吡咯(Au/PPy)纳米豆荚使用病毒模板:M13 噬菌体进行制造。经过基因修饰的丝状病毒沿其长度显示出金结合肽,允许在环境条件下选择性地附着金纳米颗粒(Au NPs)。在病毒模板化的 Au NP 链上通过电聚合聚合聚吡咯(PPy)壳,形成纳米豆荚结构。通过电沉积电位和时间控制 PPy 壳的形态和厚度,形成 17.4 ± 3.3nm 的超薄导电聚合物壳。后电沉积酸处理用于修饰这些杂化材料的电性能。在每个组装步骤监测纳米豆荚的电阻。由混合 Au/PPy 纳米结构的网络开发了化学电阻式氨(NH3)气体传感器。在 5 至 50 ppmv 的范围内评估了室温传感性能,并且观察到可逆和不可逆的化学电阻行为的混合物。对于 10 ppmv 或更低的 NH3 浓度,发现灵敏度为 0.30%/ppm,并且计算出的最低检测限(LDL)为 0.007 ppmv。此外,酸处理的器件在相同浓度范围内表现出增强的灵敏度 1.26%/ppm,并且计算出的 LDL 为 0.005 ppmv。
