钙钛矿(结构)
单层
异质结
偶极子
杰纳斯
光电子学
材料科学
电子能带结构
光伏系统
凝聚态物理
载流子
化学物理
电荷(物理)
力矩(物理)
光伏
分子物理学
光子学
带偏移量
钙钛矿太阳能电池
重组
带隙
纳米技术
偏移量(计算机科学)
载流子寿命
化学
极限(数学)
分子动力学
作者
Lili Xu,Shengli Zhang,Yee Sin Ang
出处
期刊:Nano Letters
[American Chemical Society]
日期:2025-12-17
卷期号:25 (52): 18100-18107
被引量:1
标识
DOI:10.1021/acs.nanolett.5c05145
摘要
Even though perovskite solar cells achieve high efficiency, interfacial energy mismatches with transport layers induce nonradiative recombination and limit performance. Here, we propose interface-dipole-driven band alignment engineering as a strategy to guarantee Type-II band alignment by integrating a Janus monolayer into a perovskite/Janus monolayer/perovskite heterostructure. The intrinsic out-of-plane dipole shifts the band edges of adjacent perovskite layers, thus enabling one layer to act as a light absorber and the other as a charge transport layer. Using CsPbBr3/MSSe/CsPbBr3 (M = Mo, W) as model systems, first-principles calculations confirm the formation of dipole-driven Type-II band alignment, while nonadiabatic molecular dynamics predict extended carrier lifetimes in CsPbBr3/WSSe/CsPbBr3, which can be attributed to its stronger dipole moment of monolayer WSSe and weaker nonadiabatic coupling. These results establish Janus monolayers as a versatile interfacial design platform to enhance carrier separation and suppress recombination, thus paving a way toward simplified, transport-layer-free, high-efficiency perovskite optoelectronics.
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