ACS Appl Mater Interfaces. 2018 May 2;10(17):15088-15095. doi: 10.1021/acsami.8b03433. Epub 2018 Apr 23.
A facile and scalable in situ microelectrolysis nanofabrication technique is developed for preparing cross-linked Ni(OH) nanosheets on a novel three-dimensional porous nickel template (Ni(OH)@3DPN). For the constructed template, the porogen of NaCl particles not only induces a self-limiting surficial hot corrosion to claim the "start engine stop" mechanism but also serves as the primary battery electrolyte to greatly accelerate the growth of Ni(OH). As far as we know, the microelectrolysis nanofabrication is superior to the other reported Ni(OH) synthesis methods due to the mild condition (60 °C, 6 h, NaCl solution, ambient environment) and without any post-treatment. The integrated Ni(OH)@3DPN electrode with a highly suitable microstructure and a porous architecture implies a potential application in electrochemistry. As a proof-of-concept demonstration, the electrode was employed for nonenzymatic glucose sensing, which exhibits an outstanding sensitivity of 2761.6 μA mM cm ranging from 0.46 to 2100 μM, a fast response, and a low detection limit. The microelectrolysis nanofabrication is a one-step, binder-free, entirely green, and therefore it has a distinct advantage to improve clean production and reduce energy consumption.
一种简便且可扩展的原位微电解纳米制造技术被开发出来,用于在新型三维多孔镍模板(Ni(OH)@3DPN)上制备交联的 Ni(OH)纳米片。对于构建的模板,NaCl 颗粒的造孔剂不仅诱导自限制表面热腐蚀来声称“启动发动机停止”机制,而且还用作原电池电解质,从而大大加速了 Ni(OH)的生长。据我们所知,由于温和的条件(60°C,6 h,NaCl 溶液,环境)和无需任何后处理,微电解纳米制造优于其他报道的 Ni(OH)合成方法。具有高度合适的微观结构和多孔结构的集成 Ni(OH)@3DPN 电极暗示了在电化学中的潜在应用。作为概念验证演示,该电极用于非酶葡萄糖传感,其在 0.46 至 2100 μM 的范围内表现出出色的灵敏度 2761.6 μA mM cm,快速响应和低检测限。微电解纳米制造是一步法、无粘合剂、完全绿色的,因此它具有明显的优势,可以提高清洁生产并降低能源消耗。
