用于精确控制硫化铅量子点尺寸的合成条件

Synthetic Conditions for High-Accuracy Size Control of PbS Quantum Dots.

作者信息

Zhang Jianbing, Crisp Ryan W, Gao Jianbo, Kroupa Daniel M, Beard Matthew C, Luther Joseph M

机构信息

†School of Optical and Electronic Information, Huazhong University of Science and Technology, 1037 Luoyu Road, Wuhan, Hubei 430074, China.

‡Chemical and Material Sciences Center, National Renewable Energy Laboratory, 15013 Denver West Parkway, Golden, Colorado 80401, United States.

出版信息

J Phys Chem Lett. 2015 May 21;6(10):1830-3. doi: 10.1021/acs.jpclett.5b00689. Epub 2015 May 4.

DOI:10.1021/acs.jpclett.5b00689

PMID:26263256

Abstract

Decreasing the variability in quantum dot (QD) syntheses is desirable for better uniformity of samples for use in QD-based studies and applications. Here we report a highly reproducible linear relationship between the concentration of ligand (in this case oleic acid, OA) and the lowest energy exciton peak position (nm) of the resulting PbS QDs for various hot-injection temperatures. Thus, for a given injection temperature, the size of the PbS QD product is purely controlled by the amount of OA. We used this relationship to study PbS QD solar cells that are fabricated from the same size of PbS QDs but synthesized using four different injection temperatures: 95, 120, 150, and 185 °C. We find that the power conversion efficiency does not depend on injection temperature but that the V(oc) is higher for QDs synthesized at lower temperatures while the J(sc) is improved in higher temperature QDs.

摘要

降低量子点（QD）合成过程中的变异性，对于基于量子点的研究和应用中获得更好的样品均匀性是很有必要的。在此，我们报告了在不同热注入温度下，配体（在此为油酸，OA）浓度与所得硫化铅量子点的最低能量激子峰位置（纳米）之间存在高度可重复的线性关系。因此，对于给定的注入温度，硫化铅量子点产物的尺寸完全由油酸的量控制。我们利用这种关系研究了由相同尺寸但使用四种不同注入温度（95、120、150和185°C）合成的硫化铅量子点制成的太阳能电池。我们发现功率转换效率并不取决于注入温度，但在较低温度下合成的量子点的开路电压（V(oc)）较高，而在较高温度下合成的量子点的短路电流密度（J(sc)）有所提高。

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用于精确控制硫化铅量子点尺寸的合成条件

Synthetic Conditions for High-Accuracy Size Control of PbS Quantum Dots.

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