Self‐Healing Cs3Bi2Br3I6 Perovskite Wafers for X‐Ray Detection

Self‐healing of defects imposed by external stimuli such as high energy radiation is a possibility to sustain the operational lifetime of electronic devices such as radiation detectors. Cs3Bi2Br3I6 polycrystalline wafers are introduced here as novel X‐ray detector material, which not only guarantees a high X‐ray stopping power due to its composition with elements with high atomic numbers, but also outperforms other Bi‐based semiconductors in respect to detector parameters such as detection limit, transient behavior, or dark current. The polycrystalline wafers represent a size scalable technology suitable for future integration in imager devices for medical applications. Most astonishingly, aging of these wafer‐based devices results in an overall improvement of the detector performance—dark currents are reduced, photocurrents are increased, and one of the most problematic properties of X‐ray detectors, the base line drift is reduced by orders of magnitude. These aging induced improvements indicate self‐healing effects which are shown to result from recrystallization. Optimized synthetic conditions also improve the as prepared X‐ray detectors; however, the aged device outperforms all others. Thus, self‐healing acts in Cs3Bi2Br3I6 as an optimization tool, which is certainly not restricted to this single compound, it is expected to be beneficial also for many further polycrystalline ionic semiconductors.

[1]  Laura Pernigoni,et al.  Self-healing materials for space applications: overview of present development and major limitations , 2021, CEAS Space Journal.

[2]  Q. Gong,et al.  Perovskite Solar Cells for Space Applications: Progress and Challenges , 2021, Advanced materials.

[3]  Wen-Hau Zhang,et al.  Zero-Dimensional Lead-Free FA3Bi2I9 Single Crystals for High-Performance X-ray Detection. , 2021, The journal of physical chemistry letters.

[4]  M. Kanatzidis,et al.  Inch-sized high-quality perovskite single crystals by suppressing phase segregation for light-powered integrated circuits , 2021, Science Advances.

[5]  Guangda Niu,et al.  Lead-free halide perovskite Cs3Bi2Br9 single crystals for high-performance X-ray detection , 2021, Science China Materials.

[6]  M. Kanatzidis,et al.  CsPbBr3 perovskite detectors with 1.4% energy resolution for high-energy γ-rays , 2021 .

[7]  S. Tsang,et al.  Revealing the Degradation and Self‐Healing Mechanisms in Perovskite Solar Cells by Sub‐Bandgap External Quantum Efficiency Spectroscopy , 2020, Advanced materials.

[8]  Ming-Hsuan Yang,et al.  Single Crystal CdSe X-ray Detectors with Ultra-High Sensitivity and Low Detection Limit. , 2020, ACS applied materials & interfaces.

[9]  A. Reznik,et al.  Bilayer lead oxide X-ray photoconductor for lag-free operation , 2020, Scientific reports.

[10]  Qingliang Liao,et al.  Highly Robust and Self-Powered Electronic Skin Based on Tough Conductive Self-Healing Elastomer. , 2020, ACS nano.

[11]  M. Kanatzidis,et al.  Nucleation-controlled growth of superior lead-free perovskite Cs3Bi2I9 single-crystals for high-performance X-ray detection , 2020, Nature Communications.

[12]  Q. Ramasse,et al.  Evidence for self-healing benign grain boundaries and a highly defective Sb2Se3-CdS interfacial layer in Sb2Se3 thin-film photovoltaics. , 2020, ACS applied materials & interfaces.

[13]  K. Zhao,et al.  Large and Dense Organic-Inorganic Hybrid Perovskite CH3NH3PbI3 Wafer Fabricated by One-Step Reactive Direct Wafer Production with High X-ray Sensitivity. , 2020, ACS applied materials & interfaces.

[14]  Ioannis D. Apostolopoulos,et al.  Covid-19: automatic detection from X-ray images utilizing transfer learning with convolutional neural networks , 2020, Physical and Engineering Sciences in Medicine.

[15]  X. Ouyang,et al.  CsPbBr3 Single Crystal X-ray Detector with Schottky Barrier for X-ray Imaging Application , 2020 .

[16]  C. Brabec,et al.  Sensitive Direct Converting X‐Ray Detectors Utilizing Crystalline CsPbBr3 Perovskite Films Fabricated via Scalable Melt Processing , 2020, Advanced Materials Interfaces.

[17]  G. Matt,et al.  A perspective on the bright future of metal halide perovskites for X-ray detection , 2019, Applied Physics Letters.

[18]  X. Miao,et al.  Hot‐Pressed CsPbBr3 Quasi‐Monocrystalline Film for Sensitive Direct X‐ray Detection , 2019, Advanced materials.

[19]  Haiming Zhu,et al.  Highly sensitive X-ray detector made of layered perovskite-like (NH4)3Bi2I9 single crystal with anisotropic response , 2019, Nature Photonics.

[20]  Junjia Wang,et al.  Spectral Responsivity and Photoconductive Gain in Thin Film Black Phosphorus Photodetectors , 2019, ACS Photonics.

[21]  Carmel Majidi,et al.  Self-healing materials for soft-matter machines and electronics , 2019, NPG Asia Materials.

[22]  X. Miao,et al.  Heteroepitaxial passivation of Cs2AgBiBr6 wafers with suppressed ionic migration for X-ray imaging , 2019, Nature Communications.

[23]  Suhuai Wei,et al.  Alloy-induced phase transition and enhanced photovoltaic performance: the case of Cs3Bi2I9−xBrx perovskite solar cells , 2019, Journal of Materials Chemistry A.

[24]  Intisar Ali Sajjad,et al.  Self-healing materials for electronic applications: an overview , 2019, Materials Research Express.

[25]  M. Kanatzidis,et al.  From 0D Cs3Bi2I9 to 2D Cs3Bi2I6Cl3: Dimensional Expansion Induces a Direct Band Gap but Enhances Electron–Phonon Coupling , 2019, Chemistry of Materials.

[26]  M. Thompson,et al.  Anionic order and band gap engineering in vacancy ordered triple perovskites. , 2019, Chemical communications.

[27]  Haotong Wei,et al.  Halide lead perovskites for ionizing radiation detection , 2019, Nature Communications.

[28]  S. Seok,et al.  Intrinsic Instability of Inorganic–Organic Hybrid Halide Perovskite Materials , 2019, Advanced materials.

[29]  A. Deschamps,et al.  Recent advances in the metallurgy of aluminum alloys. Part II: Age hardening , 2018, Comptes Rendus Physique.

[30]  Hui Sun,et al.  Preparation and characterization of free-standing BiI3 single-crystal flakes for X-ray detection application , 2018, Journal of Materials Science: Materials in Electronics.

[31]  Yuebin Lian,et al.  Bandgap engineering of a lead-free defect perovskite Cs3Bi2I9 through trivalent doping of Ru3+ , 2018, RSC advances.

[32]  Dieter Neher,et al.  Measuring Aging Stability of Perovskite Solar Cells , 2018 .

[33]  Cuiling Zhang,et al.  Thermodynamically Self‐Healing 1D–3D Hybrid Perovskite Solar Cells , 2018 .

[34]  Haiping Li,et al.  Synthesis and photocatalytic activity of BiOBr nanosheets with tunable crystal facets and sizes , 2018 .

[35]  Jiake Wu,et al.  Self-Healing Electronic Materials for a Smart and Sustainable Future. , 2018, ACS applied materials & interfaces.

[36]  Dan Oron,et al.  Self‐Healing Inside APbBr3 Halide Perovskite Crystals , 2018, Advances in Materials.

[37]  S. Mhaisalkar,et al.  Limitations of Cs3Bi2I9 as Lead-Free Photovoltaic Absorber Materials. , 2018, ACS applied materials & interfaces.

[38]  Guangda Niu,et al.  Cs2AgBiBr6 single-crystal X-ray detectors with a low detection limit , 2017 .

[39]  Thilo Michel,et al.  High-performance direct conversion X-ray detectors based on sintered hybrid lead triiodide perovskite wafers , 2017, Nature Photonics.

[40]  Xiaodan Gu,et al.  Intrinsically stretchable and healable semiconducting polymer for organic transistors , 2016, Nature.

[41]  Claudine Katan,et al.  Light-activated photocurrent degradation and self-healing in perovskite solar cells , 2016, Nature Communications.

[42]  C. Brabec,et al.  Perovskites target X-ray detection , 2016, Nature Photonics.

[43]  Padhraic Mulligan,et al.  Sensitive X-ray detectors made of methylammonium lead tribromide perovskite single crystals , 2016, Nature Photonics.

[44]  M. Saidaminov,et al.  Making and Breaking of Lead Halide Perovskites. , 2016, Accounts of chemical research.

[45]  Heng Li,et al.  A polymer scaffold for self-healing perovskite solar cells , 2016, Nature Communications.

[46]  C. Brabec,et al.  Detection of X-ray photons by solution-processed lead halide perovskites , 2015, Nature Photonics.

[47]  Timothy L. Kelly,et al.  Origin of the Thermal Instability in CH3NH3PbI3 Thin Films Deposited on ZnO , 2015 .

[48]  A. Walsh,et al.  Intrinsic Instability of the Hybrid Halide Perovskite Semiconductor CH3NH3PbI3 , 2015, 1506.01301.

[49]  Hao Gao,et al.  A facile, solvent vapor-fumigation-induced, self-repair recrystallization of CH3NH3PbI3 films for high-performance perovskite solar cells. , 2015, Nanoscale.

[50]  Mohammad Khaja Nazeeruddin,et al.  Understanding the rate-dependent J–V hysteresis, slow time component, and aging in CH3NH3PbI3 perovskite solar cells: the role of a compensated electric field , 2015 .

[51]  T. Fromherz,et al.  High Infrared Photoconductivity in Films of Arsenic-Sulfide-Encapsulated Lead-Sulfide Nanocrystals , 2014, ACS nano.

[52]  Zhifu Liu,et al.  Crystal Growth of the Perovskite Semiconductor CsPbBr3: A New Material for High-Energy Radiation Detection , 2013 .

[53]  Habib Mani,et al.  Amorphous and Polycrystalline Photoconductors for Direct Conversion Flat Panel X-Ray Image Sensors , 2011, Sensors.

[54]  J. H. Lee,et al.  Measurement of the drift mobilities and the mobility-lifetime products of charge carriers in a CdZnTe crystal by using a transient pulse technique , 2011 .

[55]  D. Balzar,et al.  Size-broadening anisotropy in whole powder pattern fitting. Application to zinc oxide and interpretation of the apparent crystallites in terms of physical models , 2008 .

[56]  Piotr Martyniuk,et al.  Quantum-dot infrared photodetectors: Status and outlook , 2008 .

[57]  E. Saucedo,et al.  Bismuth tri-iodide polycrystalline films for digital X-ray radiography applications , 2002, 2002 IEEE Nuclear Science Symposium Conference Record.

[58]  M. Järvinen Application of symmetrized harmonics expansion to correction of the preferred orientation effect , 1993 .

[59]  E. Anagnostakis Photoconductive gain of semiconductor epitaxial layers , 1991 .