“绿色”胶体纳米晶体形成的CZTS薄膜的结构和电学性能与铜含量相关

V. Dzhagan, O. Selyshchev, S. Kondratenko, N. Mazur, Y. Havryliuk, Oleksandra Raievska, O. Stroyuk, D. Zahn
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引用次数: 2

摘要

利用拉曼散射、中红外(分子振动)和近红外(自由载流子)吸收、x射线光电发射光谱(XPS)、电导率和导电原子力显微镜(cAFM)研究了在水中采用“绿色”方法合成的胶体CZTS纳米晶体(NCs)薄膜。我们确定了实际Cu含量对声子光谱、电导率和等离子体带光谱参数的影响。在220°C退火后,NC膜的电导率增加是由三个因素解释的:在CZTS NC表面形成CuxS纳米相,部分去除配体,以及结构完善程度的提高。CuxS相的存在是影响CZTS NC膜电导率的决定性因素。根据XPS数据和拉曼光谱数据,对铜的修正俄歇参数进行分析,可以可靠地检测到CuxS。从核能级XPS和振动红外光谱的一致性可以得出配体部分去除的结论。晶格的完美程度也可以方便地从拉曼数据中评估。从光电子和光学数据的结合中得到的进一步重要信息是NC膜的功函数、电离势和电子亲和力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Copper-Content Dependent Structural and Electrical Properties of CZTS Films Formed by “Green” Colloidal Nanocrystals
Thin films of colloidal CZTS nanocrystals (NCs) synthesized using a “green” approach in water with a variation of the copper-to-tin ratio are investigated by Raman scattering, mid-infrared (molecular vibrations) and near-infrared (free carrier) absorption, X-ray photoemission spectroscopy (XPS), electrical conductivity, and conductive atomic force microscopy (cAFM). We determined the effect of the actual Cu content on the phonon spectra, electrical conductivity, and spectral parameters of the plasmon band. An increase in the electrical conductivity of the NC films upon annealing at 220 °C is explained by three factors: formation of a CuxS nanophase at the CZTS NC surface, partial removal of ligands, and improved structural perfection. The presence of the CuxS phase is concluded to be the determinant factor for the CZTS NC film conductivity. CuxS can be reliably detected based on the analysis of the modified Auger parameter of copper, derived from XPS data and corroborated by Raman spectroscopy data. Partial removal of the ligand is concluded from the agreement of the core-level XPS and vibrational IR spectra. The degree of lattice perfection can be conveniently assessed from the Raman data as well. Further important information derived from a combination of photoelectron and optical data is the work function, ionization potential, and electron affinity of the NC films.
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