Univ. Grenoble Alpes, CEA, CNRS, IRIG, SYMMES, 38000 Grenoble, France.
Nanoscale. 2019 Nov 28;11(46):22504-22514. doi: 10.1039/c9nr03749g.
A versatile, low-cost and easily scalable synthesis method is presented for producing silicon nanowires (SiNWs) as a pure powder. It applies air-stable diphenylsilane as a Si source and gold nanoparticles as a catalyst and takes place in a sealed reactor at 420 °C (pressure <10 bar). Micron-sized NaCl particles, acting as a sacrificial support for the catalyst particles during NW growth, can simply be removed with water during purification. This process gives access to SiNWs of precisely controlled diameters in the range of 10 ± 3 nm with a high production yield per reactor volume (1 mg cm-3). The reaction was scaled up to 500 mg of SiNWs without altering the morphology or diameter. Adding diphenylphosphine results in SiNW n-type doping as confirmed by ESR spectroscopy and EDX analyses. The measured SiNW doping level closely follows the initial dopant concentration. Doping induces both an increase in diameter and a sharp increase of electrical conductivity for P concentrations >0.4%. When used in symmetric supercapacitor devices, 1% P-doped SiNWs exhibit an areal capacity of 0.25 mF cm-2 and retention of 80% of the initial capacitance after one million cycles, demonstrating excellent cycling stability of the SiNW electrodes in the presence of organic electrolytes.
本文提出了一种通用、低成本且易于扩展的硅纳米线(SiNWs)合成方法,可将其作为纯粉末制备。该方法以空气稳定的二苯基硅烷作为硅源,以金纳米颗粒作为催化剂,在 420°C(压力<10 巴)的密封反应器中进行反应。微米级的 NaCl 颗粒在 NW 生长过程中作为催化剂颗粒的牺牲支撑体,可以在提纯过程中简单地用水去除。该工艺可精确控制 SiNW 的直径在 10±3nm 范围内,每个反应器的产量很高(1mgcm-3)。反应可放大至 500mg SiNWs,而不改变形貌或直径。添加二苯膦会导致 SiNW 发生 n 型掺杂,这可通过 ESR 光谱和 EDX 分析得到证实。测量得到的 SiNW 掺杂水平与初始掺杂浓度密切相关。掺杂会导致直径增大,并且当 P 浓度>0.4%时,电导率急剧增加。在对称超级电容器器件中,1% P 掺杂的 SiNW 表现出 0.25mFcm-2 的比面积容量,并且在 100 万次循环后保留初始电容的 80%,这表明在有机电解质存在的情况下,SiNW 电极具有出色的循环稳定性。
