Research Center for Photovoltaic Technologies, AIST, Tsukuba, 305-8568, Japan.
Nanoscale. 2013 Aug 7;5(15):6725-30. doi: 10.1039/c3nr00891f.
Here we demonstrate the material's synthetic feasibility for semiconducting alloyed silicon-tin nanocrystals (SiSn-NCs) with quantum confinement effects. An environmentally friendly synthesis is achieved by ns laser ablation of amorphous SiSn in water at ambient conditions. Plasmas generated in the liquid by laser pulses are characterized by spatial confinement with very high pressure (GPa), which allowed the growth of the SiSn-NCs via kinetic pathways. We further illustrate that surface engineering by a direct-current atmospheric pressure microplasma is capable of tailoring the SiSn-NCs surface properties without the need for lengthy surfactants, resulting in room temperature photoluminescence (PL); the PL peak wavelength is red-shifted by more than 250 nm with respect to the PL peak wavelengths observed for comparable elemental silicon nanocrystals.
在这里,我们展示了具有量子限域效应的半导体合金硅锡纳米晶体 (SiSn-NCs) 的材料合成可行性。通过在环境条件下使用纳秒激光烧蚀非晶态 SiSn 在水中实现了环保合成。激光脉冲在液体中产生的等离子体具有非常高的压力 (GPa) 的空间限制,这允许通过动力学途径生长 SiSn-NCs。我们进一步说明,通过直流常压微等离子体进行的表面工程能够在无需使用长链表面活性剂的情况下对 SiSn-NCs 的表面性质进行调整,从而实现室温下的光致发光 (PL);与可比的元素硅纳米晶体相比,PL 峰波长红移超过 250nm。
