Converting vapor precursors to solid nanostructures via a liquid noble-metal seed is a common vapor deposition principle. However, such a noble-metal-seeded process is excluded from the crystalline halide perovskite synthesis, mainly hindered by the growth mechanism shortness. Herein, powered by a spontaneous exothermic nucleation process (Delta H < 0), the Au-seeded CsPbI3 nanowires (NWs) growth is realized based on a vapor-liquid-solid (VLS) growth mode. It is energetically favored that the Au seeds are reacted with a Pb vapor precursor to form molten Au-Pb droplets at temperatures down to 212 degrees C, further triggering the low-temperature VLS growth of CsPbI3 NWs. More importantly, this Au-seeded process reduces in-bandgap trap states and consequently avoids Shockley-Read-Hall recombination, contri-buting to outstanding photodetector performances. Our work extends the powerful Au-seeded VLS growth mode to the emerging halide perovskites, which will facilitate their nanostructures with tailored material properties.
展开▼
机译:通过液态贵金属晶种将气相前驱体转化为固体纳米结构是一种常见的气相沉积原理。然而,这种贵金属晶种工艺被排除在结晶卤化物钙钛矿合成之外,主要受生长机理短的阻碍。本文采用自发放热成核过程(Delta H < 0),基于气-液-固(VLS)生长模式实现了Au晶种CsPbI3纳米线(NWs)的生长。在低至212°C的温度下,Au晶种与Pb蒸气前驱体反应形成熔融的Au-Pb液滴,进一步触发了CsPbI3 NWs的低温VLS生长。更重要的是,这种金种子工艺减少了带隙内陷阱状态,从而避免了Shockley-Read-Hall复合,从而有助于实现出色的光电探测器性能。我们的工作将强大的金晶种VLS生长模式扩展到新兴的卤化物钙钛矿,这将促进其纳米结构与定制的材料特性。
展开▼
