UV-Induced Oxygen Removal for Photostable, High-Efficiency PTB7-Th:PC₇₁BM Photovoltaic Cells

Abstract: Solution-processed ZnO sol-gel or nanoparticles are widely used as the electron transporting layer (ETL) in optoelectronic devices. However, chemisorbed oxygen on the ZnO layer surface has been shown to be detrimental for the device performance as well as stability. Herein, we demonstrate that a chemisorbed oxygen removal based on a UV illumination of the ZnO surface layer under a nitrogen atmosphere can, simultaneously, improve power conversion efficiency and photostability of PTB7-Th: PC 71 BM based inverted… Show more

“…It is observed that the devices using ZnO interlayers yielded an inflection around the Voc point when they were not subjected to UV activation. This suggests that the UV activation is necessary for the induction of photoconductivity and oxygen desorption in the un-doped ZnO layer and the elimination of the electron extraction barrier as also reported by other groups and may explain the lower photovoltaic performance of our reference devices with ZnO (which were not UV activated) as compared to other works [25,55,56]. On the contrary, there was negligible change in the performance of devices using HZO interlayer under illumination without the UV component.…”

Avoiding ambient air and light induced degradation in high-efficiency polymer solar cells by the use of hydrogen-doped zinc oxide as electron extraction material

“…It is observed that the devices using ZnO interlayers yielded an inflection around the Voc point when they were not subjected to UV activation. This suggests that the UV activation is necessary for the induction of photoconductivity and oxygen desorption in the un-doped ZnO layer and the elimination of the electron extraction barrier as also reported by other groups and may explain the lower photovoltaic performance of our reference devices with ZnO (which were not UV activated) as compared to other works [25,55,56]. On the contrary, there was negligible change in the performance of devices using HZO interlayer under illumination without the UV component.…”

Avoiding ambient air and light induced degradation in high-efficiency polymer solar cells by the use of hydrogen-doped zinc oxide as electron extraction material

“…Wide bandgap n‐type semiconductors such as ZnO, TiO 2 , and CdS have been extensively employed in photovoltaic devices as they readily crystalize with good semiconducting properties from a wet‐chemical fabrication process. CdS is a typical n‐type semiconductor with higher photostability compared to ZnO and TiO 2 and the CdS films have been prepared by various methods such as Chemical Bath Deposition (CBD), sputtering, and evaporation . CdS films have been extensively studied in Cu(In,Ga)Se 2 , Cu 2 ZnSn(S,Se) 4 , and CdTe solar cells as the electron transport layer.…”

High Performance PbS Colloidal Quantum Dot Solar Cells by Employing Solution‐Processed CdS Thin Films from a Single‐Source Precursor as the Electron Transport Layer

“…PC 71 BM [34][35][36] ), we demonstrate that we can achieve a power conversion efficiency (PCE) of 11.1%, corresponding to the highest power conversion efficiency ever measured for that polymer. The applicability of this new optical cavity is quite general and may be used, in 3 principle, to enhance the performance of any other thin film photovoltaic technology.…”

A Two‐Resonance Tapping Cavity for an Optimal Light Trapping in Thin‐Film Solar Cells