Details

Autor(en) / Beteiligte

• Wang, Fengyou
• Zhang, Yuhong
• Yang, Meifang
• Fan, Lin
• Yang, Lili
• Sui, Yingrui
• Yang, Jinghai
• Zhang, Xiaodan

Titel

Toward ultra-thin and omnidirectional perovskite solar cells: Concurrent improvement in conversion efficiency by employing light-trapping and recrystallizing treatment

Ist Teil von

• Nano energy, 2019-06, Vol.60, p.198-204

Ort / Verlag

Elsevier Ltd

Erscheinungsjahr

2019

Quelle

Alma/SFX Local Collection

Beschreibungen/Notizen

• Efficient perovskite solar cells with ultra-thin absorber would be very attractive for semitransparent-, tandem-, and flexible-photovoltaic application. However, the absorber with ultra-thin thickness always cause extra optical losses due to the insufficient light-harvesting. Here, we try to stress this key factor by constructing textured substrates and appropriate control of recrystallization treatment for ultra-thin perovskite solar cells that synergizes the merits characters including good broad-band, enhanced light-trapping and excellent separation/collection of photo-generated charges. In particularly, the isopropanol (IPA) - assisted recrystallizing treatment enable to form pinholes free perovskite films on a high-aspect-ratio substrate, which relax the trade-off between the optical enhancements and electrical deteriorations. The perovskite solar cell exhibits an efficiency of 18.6% by using an only ∼200-nm MAPbI3 as the absorber, which is a record efficiency for such thin-perovskite solar cells. We also exhibit the solar cells that shows the enhancement of daily generated power to 47.6% by using the crater-like architecture, as compared to traditional planar devices. The concurrent enhancement in optical and electrical performance for achieving high-efficiency perovskite solar cells with thin absorber demonstrated here makes a simple process promising for photoelectric device application. [Display omitted] •Quasi-omnidirectional perovskite solar cell with ultra-thin absorber has been prepared.•Efficient light trapping has achieved by employing crater-textured substrates.•Interface defects have been effectively eliminated by the proposed recrystallizing treatment.•A high efficiency of 18.6% have been achieved for ∼200 nm perovskite solar cells.