Litcius/Paper detail

Functionalized-MXene-nanosheet-doped tin oxide enhances the electrical properties in perovskite solar cells

Li Yin, Chenguang Liu, Changzeng Ding, Chun Zhao, Chun Zhao, Ivona Z. Mitrović, Eng Gee Lim, Haibin Wang, Yi Sun, Yunfei Han, Zerui Li, Li Yang, Chang‐Qi Ma, Cezhou Zhao, Cezhou Zhao

2022Cell Reports Physical Science46 citationsDOIOpen Access PDF

Abstract

An appropriate electron transport layer (ETL) with better energy alignment and enhanced charge transfer, thereby helping efficient extraction and transport of photogenerated carriers, is essential to achieve the creation of high-performance devices. In this work, we use functionalized MXene modified with fluoroalkylsilane and dodecyltrimethoxysilane molecules, denoted as SnO2-MF and SnO2-MH, as nanosheet dopants in the SnO2 ETL. From density functional theory (DFT) calculations and ultraviolet photoelectron spectra (UPS) spectra, we see that better band alignment is achieved for the SnO2-MH ETL. Meanwhile, functionalized MXene nanosheets represent high electrical conductivity and mobility and could form zero Schottky barrier heterojunction with SnO2, effectively and rapidly enhancing carrier transfer. Finally, the suitable surface energy achieved by functionalized MXene additives can enlarge the grain size of perovskite thin films. Consequently, a significant improvement of power conversion efficiency (PCE) from 20.98% to 23.66% (24.12% for the champion device with a fill factor [FF] over 0.84) can be achieved for devices based on the SnO2-MH ETL, which also possess improved moisture resistance and operational stability.

Topics & Concepts

Materials scienceNanosheetPerovskite (structure)Ultraviolet photoelectron spectroscopyHeterojunctionSchottky barrierDopingOptoelectronicsDopantTin dioxideTin oxideChemical engineeringNanotechnologyX-ray photoelectron spectroscopyDiodeEngineeringMetallurgyPerovskite Materials and ApplicationsMXene and MAX Phase Materials2D Materials and Applications