Atomically Resolved Electrically Active Intragrain Interfaces in Perovskite Semiconductors

Deciphering the atomic and electronic structures of interfaces is key to developing state-of-the-art perovskite semiconductors. However, conventional characterization techniques have limited previous studies mainly to grain-boundary interfaces, whereas the intragrain-interface microstructures and their electronic properties have been much less revealed. Herein using scanning transmission electron microscopy, we resolved the atomic-scale structural information on three prototypical intragrain interfaces, unraveling intriguing features clearly different from those from previous observations based on standalone films or nanomaterial samples. These intragrain interfaces include composition boundaries formed by heterogeneous ion distribution, stacking faults resulted from wrongly stacked crystal planes, and symmetrical twinning boundaries. The atomic-scale imaging of these intragrain interfaces enables us to build unequivocal models for the ab initio calculation of electronic properties. Our results suggest that these structure interfaces are generally electronically benign, whereas their dynamic interaction with point defects can still evoke detrimental effects. This work paves the way toward a more complete fundamental understanding of the microscopic structure–property–performance relationship in metal halide perovskites.

[1]  Weijian Chen,et al.  The critical role of composition-dependent intragrain planar defects in the performance of MA1–xFAxPbI3 perovskite solar cells , 2021, Nature Energy.

[2]  Jinsong Huang,et al.  Defect compensation in formamidinium–caesium perovskites for highly efficient solar mini-modules with improved photostability , 2021, Nature Energy.

[3]  Jun Hee Lee,et al.  Pseudo-halide anion engineering for α-FAPbI3 perovskite solar cells , 2021, Nature.

[4]  Wenjun Zhang,et al.  Slot-die coating large-area formamidinium-cesium perovskite film for efficient and stable parallel solar module , 2021, Science Advances.

[5]  J. Maier,et al.  Ion Transport, Defect Chemistry, and the Device Physics of Hybrid Perovskite Solar Cells , 2021 .

[6]  A. Walsh,et al.  Modeling Grain Boundaries in Polycrystalline Halide Perovskite Solar Cells , 2020, Annual Review of Condensed Matter Physics.

[7]  S. Cai,et al.  Visualizing the Invisible in Perovskites , 2020, Joule.

[8]  P. Nellist,et al.  Atomic-scale microstructure of metal halide perovskite , 2020, Science.

[9]  U. Rothlisberger,et al.  Vapor-assisted deposition of highly efficient, stable black-phase FAPbI3 perovskite solar cells , 2020, Science.

[10]  Dong Suk Kim,et al.  Stable perovskite solar cells with efficiency exceeding 24.8% and 0.3-V voltage loss , 2020, Science.

[11]  L. Qiu,et al.  A holistic approach to interface stabilization for efficient perovskite solar modules with over 2,000-hour operational stability , 2020, Nature Energy.

[12]  Yuanyuan Zhou,et al.  Anomalous 3D nanoscale photoconduction in hybrid perovskite semiconductors revealed by tomographic atomic force microscopy , 2020, Nature Communications.

[13]  Peiyi Wang,et al.  Direct atomic scale characterization of the surface structure and planar defects in the organic-inorganic hybrid CH3NH3PbI3 by Cryo-TEM , 2020 .

[14]  G. Cui,et al.  Cs4PbI6‐Mediated Synthesis of Thermodynamically Stable FA0.15Cs0.85PbI3 Perovskite Solar Cells , 2020, Advanced materials.

[15]  Ji-cai Feng,et al.  General Decomposition Pathway of Organic–Inorganic Hybrid Perovskites through an Intermediate Superstructure and its Suppression Mechanism , 2020, Advanced materials.

[16]  I. Mora‐Seró,et al.  Stabilization of Black Perovskite Phase in FAPbI3 and CsPbI3 , 2020, ACS Energy Letters.

[17]  Jinsong Huang,et al.  Benign ferroelastic twin boundaries in halide perovskites for charge carrier transport and recombination , 2020, Nature Communications.

[18]  Jiangyu Li,et al.  Transmission electron microscopy of organic-inorganic hybrid perovskites: myths and truths. , 2020, Science bulletin.

[19]  Andrew H. Proppe,et al.  Multi-cation perovskites prevent carrier reflection from grain surfaces , 2020, Nature Materials.

[20]  Yu Han,et al.  Atomic‐Resolution Imaging of Halide Perovskites Using Electron Microscopy , 2020, Advanced Energy Materials.

[21]  Yi Du,et al.  Ligand-assisted cation-exchange engineering for high-efficiency colloidal Cs1−xFAxPbI3 quantum dot solar cells with reduced phase segregation , 2020, Nature Energy.

[22]  Zhenghong Lu,et al.  Managing grains and interfaces via ligand anchoring enables 22.3%-efficiency inverted perovskite solar cells , 2020 .

[23]  Yi Cui,et al.  Unravelling Atomic Structure and Degradation Mechanisms of Organic-Inorganic Halide Perovskites by Cryo-EM. , 2019, Joule.

[24]  E. Tsymbal,et al.  Freestanding crystalline oxide perovskites down to the monolayer limit , 2019, Nature.

[25]  A. Alberti,et al.  Pb clustering and PbI2 nanofragmentation during methylammonium lead iodide perovskite degradation , 2019, Nature Communications.

[26]  Yang Yang,et al.  Supersymmetric laser arrays , 2019, Nature Photonics.

[27]  Yuanyuan Zhou,et al.  Transmission Electron Microscopy of Halide Perovskite Materials and Devices , 2019, Joule.

[28]  Tae Joo Shin,et al.  Efficient, stable and scalable perovskite solar cells using poly(3-hexylthiophene) , 2019, Nature.

[29]  A. Thind,et al.  Atomic Structure and Electrical Activity of Grain Boundaries and Ruddlesden–Popper Faults in Cesium Lead Bromide Perovskite , 2018, Advanced materials.

[30]  Yuanyuan Zhou,et al.  Synthetic Approaches for Halide Perovskite Thin Films. , 2018, Chemical reviews.

[31]  Lin-Wang Wang,et al.  Design Principles for Trap-Free CsPbX3 Nanocrystals: Enumerating and Eliminating Surface Halide Vacancies with Softer Lewis Bases. , 2018, Journal of the American Chemical Society.

[32]  Anders Hagfeldt,et al.  Methylammonium-free, high-performance, and stable perovskite solar cells on a planar architecture , 2018, Science.

[33]  Jinsong Hu,et al.  Thermodynamically Stable Orthorhombic γ-CsPbI3 Thin Films for High-Performance Photovoltaics. , 2018, Journal of the American Chemical Society.

[34]  Ayan A. Zhumekenov,et al.  Probing buried recombination pathways in perovskite structures using 3D photoluminescence tomography† †Electronic supplementary information (ESI) available. See DOI: 10.1039/c8ee00928g , 2018, Energy & environmental science.

[35]  Philip Schulz,et al.  Tailored interfaces of unencapsulated perovskite solar cells for >1,000 hour operational stability , 2018 .

[36]  J. Etheridge,et al.  Microstructural Characterisations of Perovskite Solar Cells – From Grains to Interfaces: Techniques, Features, and Challenges , 2017 .

[37]  T. Buonassisi,et al.  Promises and challenges of perovskite solar cells , 2017, Science.

[38]  J. Berry,et al.  In situ investigation of halide incorporation into perovskite solar cells , 2017, MRS Communications.

[39]  H. Boyen,et al.  Band Gap Tuning via Lattice Contraction and Octahedral Tilting in Perovskite Materials for Photovoltaics. , 2017, Journal of the American Chemical Society.

[40]  P. Kabos,et al.  Methylammonium lead iodide grain boundaries exhibit depth-dependent electrical properties , 2016 .

[41]  David S. Ginger,et al.  Photoluminescence Lifetimes Exceeding 8 μs and Quantum Yields Exceeding 30% in Hybrid Perovskite Thin Films by Ligand Passivation , 2016 .

[42]  J. Berry,et al.  Effect of Water Vapor, Temperature, and Rapid Annealing on Formamidinium Lead Triiodide Perovskite Crystallization , 2016 .

[43]  A. Di Carlo,et al.  In situ observation of heat-induced degradation of perovskite solar cells , 2016, Nature Energy.

[44]  D. Ginger,et al.  Impact of microstructure on local carrier lifetime in perovskite solar cells , 2015, Science.

[45]  S. Pennycook,et al.  Observation of a periodic array of flux-closure quadrants in strained ferroelectric PbTiO3 films , 2015, Science.

[46]  Tingting Shi,et al.  Unique Properties of Halide Perovskites as Possible Origins of the Superior Solar Cell Performance , 2014, Advanced materials.

[47]  Yanfa Yan,et al.  Unusual defect physics in CH3NH3PbI3 perovskite solar cell absorber , 2014 .

[48]  F. Hussain,et al.  Interaction of point defects with twin boundaries in Au: A molecular dynamics study , 2013 .

[49]  Anubhav Jain,et al.  Python Materials Genomics (pymatgen): A robust, open-source python library for materials analysis , 2012 .

[50]  S. Pennycook,et al.  Atom-by-atom structural and chemical analysis by annular dark-field electron microscopy , 2010, Nature.

[51]  Y. Mishin,et al.  Interaction of Point Defects with Grain Boundaries in fcc Metals , 2003 .