期刊
ACS APPLIED MATERIALS & INTERFACES
卷 10, 期 6, 页码 6006-6013出版社
AMER CHEMICAL SOC
DOI: 10.1021/acsami.7b17701
关键词
spatial ALD; tin oxide; roll-to-roll compatible solar cells; perovskite solar cells; stability of perovskite solar cells
资金
- German Federal Ministry for Education and Research [03EK3529E, 13N13819, 13N12889]
- Deutsche Forschungsgemeinschaft (DFG) [RI1551/4-2]
- European Research Council (ERC) under the European Union [637367]
Despite the notable success of hybrid halide perovskite-based solar cells, their long-term stability is still a key-issue. Aside from optimizing the photoactive perovskite, the cell design states a powerful lever to improve stability under various stress conditions. Dedicated electrically conductive diffusion barriers inside the cell stack, that counteract the ingress of moisture and prevent the migration of corrosive halogen species, can substantially improve ambient and thermal stability. Although atomic layer deposition (ALD) is excellently suited to prepare such functional layers, ALD suffers from the requirement of vacuum and only allows for a very limited throughput. Here, we demonstrate for the first time spatial ALD-grown SnOx at atmospheric pressure as impermeable electron extraction layers for perovskite solar cells. We achieve optical transmittance and electrical conductivity similar to those in SnOx grown by conventional vacuum-based ALD. A low deposition temperature of 80 degrees C and a high substrate speed of 2.4 m min(-1) yield SnOx layers with a low water vapor transmission rate of similar to 10(-4) gm(-2) day(-1) (at 60 degrees C/60% RH). Thereby, in perovskite solar cells, dense hybrid Al:ZnO/SnOx electron extraction layers are created that are the key for stable cell characteristics beyond 1000 h in ambient air and over 3000 h at 60 degrees C. Most notably, our work of introducing spatial ALD at atmospheric pressure paves the way to the future roll-to-roll manufacturing of stable perovskite solar cells.
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