Abstract
All-inorganic CsPbI(3)holds promise for efficient tandem solar cells, but reported fabrication techniques are not transferrable to scalable manufacturing methods. Herein, printable CsPbI(3)solar cells are reported, in which the charge transporting layers and photoactive layer are deposited by fast blade-coating at a low temperature (<= 100 degrees C) in ambient conditions. High-quality CsPbI(3)films are grown via introducing a low concentration of the multifunctional molecular additive Zn(C6F5)(2), which reconciles the conflict between air-flow-assisted fast drying and low-quality film including energy misalignment and trap formation. Material analysis reveals a preferential accumulation of the additive close to the perovskite/SnO(2)interface and strong chemisorption on the perovskite surface, which leads to the formation of energy gradients and suppressed trap formation within the perovskite film, as well as a 150 meV improvement of the energetic alignment at the perovskite/SnO(2)interface. The combined benefits translate into significant enhancement of the power conversion efficiency to 19% for printable solar cells. The devices without encapsulation degrade only by approximate to 2% after 700 h in air conditions.