Arghyadeep Basu, Nathan Rafisiman, Saar Shaek, Rachel Lifer, Vivek Yadav, Yaron Kauffmann, Yehonadav Bekenstein, Lev Chuntonov
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引用次数: 0
摘要
用硫氰酸根阴离子对包晶石纳米晶体表面进行功能化处理,是通过表面缺陷钝化提高稳定性和光致发光量子产率(PLQY)的一种变革性方法。本研究探讨了硫氰酸配体在改变 CsPbBr3 纳米晶体光电特性中的作用。我们采用超快二维红外光谱来研究硫氰酸配体与纳米晶体表面动态相互作用的性质,从而深入了解观察到的 PLQY 和稳定性增加的内在机制。我们的分析表明,硫氰酸配体有效地钝化了表面缺陷,从而提高了经处理的纳米晶体的 PLQY 和稳定性。光谱证据支持这样一种模型:硫氰酸盐与配位不足的铅原子结合,有助于形成稳定的纳米晶体表面,从而提高光电性能。这种配体诱导的钝化机制加深了我们对表面化学在优化太阳能电池和 LED 应用纳米材料中的作用的理解。
Insights into thiocyanate-enhanced photoluminescence in CsPbBr3 nanocrystals by ultrafast two-dimensional infrared spectroscopy
Functionalization of perovskite nanocrystal surfaces with thiocyanate anions presents a transformative approach to enhancing stability and photoluminescence quantum yield (PLQY) through surface defect passivation. This study investigates the role of thiocyanate ligands in modifying the optoelectronic properties of CsPbBr3 nanocrystals. We employed ultrafast two-dimensional infrared spectroscopy to investigate the nature of the dynamic interaction of thiocyanate ligands with nanocrystal surfaces, providing insights into the mechanisms underlying the observed increase in PLQY and stability. Our analysis reveals that the thiocyanate ligands efficiently passivate the surface defects, thereby enhancing the PLQY and the stability of the treated nanocrystals. The spectroscopic evidence supports a model where thiocyanate binds to under-coordinated lead atoms, contributing to a stable nanocrystal surface with enhanced optoelectronic performance. This ligand-induced passivation mechanism advances our understanding of surface chemistry's role in optimizing nanomaterials for solar cell and LED applications.
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