材料科学
钙钛矿(结构)
拉伤
纳米晶
化学物理
卤化物
纳米技术
化学
结晶学
凝聚态物理
无机化学
物理
内科学
医学
作者
Saar Shaek,Sasha Khalfin,Emma H. Massasa,Arad Lang,Shai Levy,Lotte T. J. Kortstee,Betty Shamaev,Shaked Dror,Rachel Lifer,Reut Shechter,Yaron Kauffmann,Rotem Strassberg,Iryna Polishchuk,Andrew Barnabas Wong,Boaz Pokroy,Ivano E. Castelli,Yehonadav Bekenstein
标识
DOI:10.1021/acs.chemmater.3c01771
摘要
Lead-free perovskite nanocrystals are of interest due to their nontoxicity and potential application in the display industry. However, engineering their optical properties is nontrivial and demands an understanding of emission from both self-trapped and free excitons. Here, we focus on tuning silver-based double perovskite nanocrystals’ optical properties via two iso-valent dopants, Bi and Sb. The photoluminescence quantum yield of the intrinsic Cs2Ag1–yNayInCl6 perovskite increased dramatically upon doping. However, the two dopants affect the optical properties very differently. We hypothesize that the differences arise from their differences in electronic level contributions and ionic sizes. This hypothesis is validated through absorption and temperature dependence photoluminescence measurements, namely, by employing the Huang–Rhys factor, which indicates the coupling of the exciton to the lattice environment. The larger ionic size of Bi also plays a role in inducing significant microstraining verified via synchrotron measurements. These differences make Bi more sensitive to doping concentration over antimony which displays brighter emission (QY ∼40%). Such understanding is important for engineering optical properties in double perovskites, especially in light of recent achievements in boosting the photoluminescence quantum yield.
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