材料科学
钙钛矿(结构)
相对湿度
原子层沉积
卤化物
成核
氧化物
光伏系统
化学工程
水蒸气
氧气
水分
光电子学
金属
湿度
阻挡层
铝
降级(电信)
臭氧
化学气相沉积
氧化铝
沉积(地质)
堆栈(抽象数据类型)
纳米线
纳米技术
无机化学
图层(电子)
活动层
钙钛矿太阳能电池
析氧
太阳能电池
作者
Melissa Davis,Kelly Schutt,Duong Nguyen Minh,X. Zhang,Chenchao Xie,Ross A. Kerner,Tianran Liu,Matthew O. Reese,Laura T. Schelhas,Michael Kempe,Axel F. Palmstrom,Joseph M. Luther
摘要
ABSTRACT Current encapsulation architectures for thin‐film metal halide perovskite do not adequately eliminate all ambient stressors. Here, we develop low transmission rate barrier layers using atomic layer deposited (ALD) aluminum oxide grown directly on the completed photovoltaic (PV) device stack to provide an additional seal, prior to full packaging. We investigate the effect of deposition temperature and oxidant chemistries on the barrier growth for protection of perovskite photovoltaic devices. We characterize the layers individually, then integrate into devices to detail the tradeoff between protection and deposition compatibility. To enhance compatibility and impermeability, we present an approach using water as the aluminum oxidant during nucleation and switching from water to ozone for the remainder of the growth. At 50 nm, the barrier results in a water vapor transmission rate (WVTR) of 4.5·10 −4 g/m 2 /day, and 1,000‐hour device stability under 45°C with 85% relative humidity without further packaging. This barrier provides sufficient protection to enable minimal degradation of the perovskite solar cells while completely submerged in water for 140 minutes. Additionally, we characterize the oxygen transmission rate (OTR) to be 0.49 cm 3 /m 2 /day at 23°C and 0% relative humidity, which is 1.5 orders of magnitude improvement over the OTR of the current encapsulation.
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