材料科学
光伏
量子点
纳米技术
掺杂剂
电极
能量转换效率
光电子学
带隙
化学工程
光伏系统
兴奋剂
化学
工程类
物理化学
生物
生态学
作者
Hyung Ryul You,Seongeun Lee,Duck Hoon Lee,G. Murali,Arun S. Nissimagoudar,Younghoon Kim,Seongmin Park,Jihoon Lee,Seon Joon Kim,Taiho Park,Byung Joon Moon,Young Ho Park,Soo‐Kwan Kim,Han Yu,Hae Jeong Kim,Wonjong Lee,Gayoung Ham,Hyeonji Lee,Seung‐Cheol Lee,Hyojung Cha
标识
DOI:10.1002/aenm.202301648
摘要
Abstract Despite recent advances in colloidal quantum dot (CQD) photovoltaics, several challenges persist and hinder further improvements. In particular, the Fermi level mismatch between the iodide‐treated photoactive and thiol‐treated hole‐transporting CQD layers creates an unfavorable energy band for hole collection. Furthermore, the numerous surface cracks in the thiol‐treated CQD layer facilitate direct contact between the photoactive CQD layer and the metal electrode, consequently leading to reduced device performance. To address these issues, a polycatechol functionalized MXene (PCA‐MXene) that can serve both as a dopant and an interlayer for CQD photovoltaics is developed. By achieving a uniformly dispersed mixture in a butylamine solvent, PCA‐MXene enables the effective combination of MXene and CQDs. This results in the modification of the work function of CQDs and the modulation of the energy band alignment, ultimately promoting enhanced hole extraction. Moreover, the PCA‐MXene employed as an interlayer effectively covers the surface cracks present in the thiol‐treated CQD layer. This coverage inhibits both metal electrode penetration and moisture intrusion into the device. Owing to these advantages, the CQD photovoltaics incorporating PCA‐MXene achieve a power conversion efficiency (PCE) of 13.6%, accompanied by enhanced thermal stability, in comparison to the reference device with a PCE of 12.8%.
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