Department of Materials Science and Engineering, Technion - Israel Institute of Technology, 32000 Haifa, Israel.
Nanoscale. 2017 Oct 5;9(38):14458-14466. doi: 10.1039/c7nr04004k.
Nanoporous gold is widely used in research and nanotechnology because of its diverse properties, including high surface area and catalytic activity. The ligament size is usually considered as one of the main parameters controlling thermal stability and mechanical properties of nanoporous gold. Recently we developed a method for creating nanoporous single crystal gold particles using eutectic decomposition of Au-Ge, followed by selective etching of Ge. Here, we used this novel method to create nanoporous gold particles with controlled ligament sizes by changing the initial sample's relative concentrations of gold and germanium. When investigated over 1-4 h at 250-400 °C the material was thermally stable up to 350 °C, which is higher than the thermal stability of "classical" nanoporous gold prepared by dealloying. Mechanical properties were examined utilizing nanoindentation of nanoporous gold before and after annealing. For smaller ligament sizes, hardness increased with annealing temperature up to 300 °C and then strongly decreased. For larger ligament sizes, hardness decreased with increasing annealing temperature. Young's modulus was unchanged up to 300 °C.
纳米多孔金因其具有高比表面积和催化活性等多种特性,被广泛应用于研究和纳米技术领域。连接体尺寸通常被认为是控制纳米多孔金热稳定性和力学性能的主要参数之一。最近,我们开发了一种使用金-锗共晶分解,随后选择性刻蚀锗的方法来制备纳米多孔单晶金颗粒。在这里,我们通过改变初始样品中金和锗的相对浓度,使用这种新方法来制备具有可控连接体尺寸的纳米多孔金颗粒。在 250-400°C 下加热 1-4 小时,该材料在 350°C 以下热稳定,高于通过脱合金制备的“经典”纳米多孔金的热稳定性。利用纳米压痕法在退火前后对纳米多孔金的力学性能进行了测试。对于较小的连接体尺寸,硬度随退火温度升高至 300°C 而升高,然后急剧下降。对于较大的连接体尺寸,硬度随退火温度的升高而降低。杨氏模量在 300°C 以下保持不变。