On the basis of experiment and theory, a general paradigm is drawn that reconsiders N2 not simply being an inert species but rather an effective healing gas molecule if entering a methylammonium lead iodide (MAPbI3) layer. Nitrogen is soaked into polycrystalline MAPbI3 via a postdeposition mild thermal treatment under slightly overpressure conditions to promote its diffusion across the whole layer. A significant reduction of radiative recombi- nation and a concurrent increase of light absorption, with a maximum benefit at 80 °C, are observed. Concomitantly, the current of holes drawn from the surfaces with nanometer resolution through a biased tip is raised by a factor of 3 under N2. This is framed by a reduction of the barrier for carrier extrac- tion. The achieved improvements are linked to a nitrogen-assisted recovery of intrinsic lattice disorder at the grain shells along with a simultaneous stabilization of undercoordinated Pb2+ and MA+ cations through weak electro- static interactions. Defect mitigation under N2 is reinforced in comparison to the benchmark behavior under argon. It is additionally unveiled that surface stabilization through N2 is morphology-independent and thus can be applied after any preparation procedure. Such simple and low-cost strategy can com- plement other stabilizing solutions for perovskite solar cells or light-emitting diode engineering.

Nitrogen Soaking Promotes Lattice Recovery in Polycrystalline Hybrid Perovskites

Alberti Alessandra;Deretzis Ioannis;Mannino Giovanni;Smecca Emanuele;Giannazzo Filippo;Listorti Andrea;Colella Silvia;Masi Sofia;La Magna Antonino
2019

Abstract

On the basis of experiment and theory, a general paradigm is drawn that reconsiders N2 not simply being an inert species but rather an effective healing gas molecule if entering a methylammonium lead iodide (MAPbI3) layer. Nitrogen is soaked into polycrystalline MAPbI3 via a postdeposition mild thermal treatment under slightly overpressure conditions to promote its diffusion across the whole layer. A significant reduction of radiative recombi- nation and a concurrent increase of light absorption, with a maximum benefit at 80 °C, are observed. Concomitantly, the current of holes drawn from the surfaces with nanometer resolution through a biased tip is raised by a factor of 3 under N2. This is framed by a reduction of the barrier for carrier extrac- tion. The achieved improvements are linked to a nitrogen-assisted recovery of intrinsic lattice disorder at the grain shells along with a simultaneous stabilization of undercoordinated Pb2+ and MA+ cations through weak electro- static interactions. Defect mitigation under N2 is reinforced in comparison to the benchmark behavior under argon. It is additionally unveiled that surface stabilization through N2 is morphology-independent and thus can be applied after any preparation procedure. Such simple and low-cost strategy can com- plement other stabilizing solutions for perovskite solar cells or light-emitting diode engineering.
2019
Istituto per la Microelettronica e Microsistemi - IMM
defects
in situ
mitigation
stability
surfaces
thermal cycle
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/20.500.14243/344261
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