Unraveling Energetic Disorder in Organic Bulk Heterojunction Photovoltaics by Capacitance-Voltage Spectroscopy
Xixiang Zhu, Kai Wang, Changfeng Han, Qin Yang, Xiaojuan Sun, Haomiao, Yu, Ming Shao, Fujun Zhang, Bin Hu

TL;DR
This study uses capacitance-voltage spectroscopy to analyze how interface interactions affect energetic disorder in organic photovoltaics, revealing implications for optimizing device performance.
Contribution
It introduces a method to assess interface-dependent energetic disorder in organic BHJ solar cells using C-V spectroscopy and models of density of states.
Findings
Energetic disorder varies with different interfaces in BHJ solar cells.
C-V profiles reflect disorder changes modeled by exponential or Gaussian DOS.
Interface modifications impact open-circuit voltage and efficiency.
Abstract
Organic semiconductors possess an intrinsic energetic disorder characteristic, which holds an exceptionally important role for understanding organic photovoltaic (OPV) operation and future optimization. We performed illumination intensity dependence of capacitance-voltage (C-V) measurements in PIDTDTQx:PC70BM based organic bulk heterojunction (BHJ) photovoltaics in working conditions. Energetic disorder profiles for the photo-active layer, PIDTDTQx:PC70BM, changed significantly when different interfaces were involved. The effects of energetic disorder that could be reflected from C-V profiles are incorporated through an exponential or Gaussian model of density of states (DOS), or a combination of these two. Results underlie that an identical organic blend in BHJ solar cells exhibits different energetic disorder when it interacts with various interfaces. It may, thus, has a certain…
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Taxonomy
TopicsOrganic Electronics and Photovoltaics · Silicon and Solar Cell Technologies · Machine Learning in Materials Science
