工作职能
材料科学
单层
氧化物
X射线光电子能谱
化学吸附
电导率
非阻塞I/O
镍
密度泛函理论
结合能
氧化镍
兴奋剂
化学物理
化学工程
分析化学(期刊)
图层(电子)
光电子学
纳米技术
物理化学
计算化学
有机化学
原子物理学
冶金
化学
吸附
催化作用
工程类
物理
作者
Sebastian Hietzschold,Sabina Hillebrandt,Florian Ullrich,Jakob Bombsch,Valentina Rohnacher,Shuangying Ma,Wenlan Liu,Andreas Köhn,Wolfram Jaegermann,Annemarie Pucci,Wolfgang Kowalsky,Eric Mankel,Sebastian Beck,Robert Lovrinčić
标识
DOI:10.1021/acsami.7b12784
摘要
Nickel oxide (NiO) is a widely used material for efficient hole extraction in optoelectronic devices. However, its surface characteristics strongly depend on the processing history and exposure to adsorbates. To achieve controllability of the electronic and chemical properties of solution-processed nickel oxide (sNiO), we functionalize its surface with a self-assembled monolayer (SAM) of 4-cyanophenylphosphonic acid. A detailed analysis of infrared and photoelectron spectroscopy shows the chemisorption of the molecules with a nominal layer thickness of around one monolayer and gives an insight into the chemical composition of the SAM. Density functional theory calculations reveal the possible binding configurations. By the application of the SAM, we increase the sNiO work function by up to 0.8 eV. When incorporated in organic solar cells, the increase in work function and improved energy level alignment to the donor does not lead to a higher fill factor of these cells. Instead, we observe the formation of a transport barrier, which can be reduced by increasing the conductivity of the sNiO through doping with copper oxide. We conclude that the widespread assumption of maximizing the fill factor by only matching the work function of the oxide charge extraction layer with the energy levels in the active material is a too narrow approach. Successful implementation of interface modifiers is only possible with a sufficiently high charge carrier concentration in the oxide interlayer to support efficient charge transfer across the interface.
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