Epitaxial Metal Halide Perovskites by Inkjet-Printing on Various Substrates

Sytnyk Mykhailo; Yousefi-Amin Amir-Abbas; Freund Tim; Prihoda Annemarie; Goetz Klaus; Unruh Tobias; Harreiss Christina; Will Johannes; Spiecker Erdmann; Levchuk Jevgen; Osvet Andres; Brabec Christoph J.; Kuenecke Ulrike; Wellmann Peter; Volobuev Valentin V.; Korczak Jedrzej; Szczerbakow Andrzej; Story Tomasz; Simbrunner Clemens; Springholz Gunther; Wechsler Daniel; Lytken Ole; Lotter Sebastian; Kampmann Felix; Maultzsch Janina; Singh Kamalpreet; Voznyy Oleksandr; Heiss Wolfgang

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Epitaxial Metal Halide Perovskites by Inkjet-Printing on Various Substrates

机译：通过喷墨印刷在各种基材上的外延金属卤化物钙锌矿

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Metal-halide-perovskites revolutionized the field of thin-film semiconductor technology, due to their favorable optoelectronic properties and facile solution processing. Further improvements of perovskite thin-film devices require structural coherence on the atomic scale. Such perfection is achieved by epitaxial growth, a method that is based on the use of high-end deposition chambers. Here epitaxial growth is enabled via a approximate to 1000 times cheaper device, a single nozzle inkjet printer. By printing, single-crystal micro- and nanostructure arrays and crystalline coherent thin films are obtained on selected substrates. The hetero-epitaxial structures of methylammonium PbBr(3)grown on lattice matching substrates exhibit similar luminescence as bulk single crystals, but the crystals phase transitions are shifted to lower temperatures, indicating a structural stabilization due to interfacial lattice anchoring by the substrates. Thus, the inkjet-printing of metal-halide perovskites provides improved material characteristics in a highly economical way, as a future cheap competitor to the high-end semiconductor growth technologies.

机译：金属卤化物 - 佩罗夫斯基酯彻底改变了薄膜半导体技术领域，由于它们有利的光电性能和易于解决方案加工。钙钛矿薄膜器件的进一步改进需要原子尺度的结构相干性。通过外延生长实现这种完美，这是基于使用高端沉积室的方法。这里通过近似到1000倍便宜的装置，单个喷嘴喷墨打印机启用外延生长。通过印刷，在选定的基材上获得单晶微型和纳米结构阵列和晶体相干薄膜。在晶格匹配衬底上生长的甲基PBBR（3）的异质外延结构表现出类似的发光，作为散装单晶，但晶体相转变被移位到较低的温度，表示由于基材的界面晶格引起的结构稳定。因此，金属卤化物钙钛矿的喷墨印刷以高度经济的方式提供了改进的材料特征，作为高端半导体生长技术的未来廉价竞争对手。

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来源
《Advanced Functional Materials》 |2020年第43期|2004612.1-2004612.10|共10页
作者
Sytnyk Mykhailo; Yousefi-Amin Amir-Abbas; Freund Tim; Prihoda Annemarie; Goetz Klaus; Unruh Tobias; Harreiss Christina; Will Johannes; Spiecker Erdmann; Levchuk Jevgen; Osvet Andres; Brabec Christoph J.; Kuenecke Ulrike; Wellmann Peter; Volobuev Valentin V.; Korczak Jedrzej; Szczerbakow Andrzej; Story Tomasz; Simbrunner Clemens; Springholz Gunther; Wechsler Daniel; Lytken Ole; Lotter Sebastian; Kampmann Felix; Maultzsch Janina; Singh Kamalpreet; Voznyy Oleksandr; Heiss Wolfgang;
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Friedrich Alexander Univ Erlangen Nurnberg Dept Mat Sci & Engn Inst Mat Elect & Energy Technol Energy Campus Nurnberg Furtherstr 250 D-90429 Nurnberg Germany;

Friedrich Alexander Univ Erlangen Nurnberg Dept Mat Sci & Engn Inst Mat Elect & Energy Technol Energy Campus Nurnberg Furtherstr 250 D-90429 Nurnberg Germany;

Friedrich Alexander Univ Erlangen Nurnberg Dept Mat Sci & Engn Inst Mat Elect & Energy Technol Energy Campus Nurnberg Furtherstr 250 D-90429 Nurnberg Germany;

Friedrich Alexander Univ Erlangen Nurnberg Inst Phys Kondensierten Mat Staudtstr 3 D-91058 Erlangen Germany|Friedrich Alexander Univ Erlangen Nurnberg Ctr Nanoanal & Electron Microscopy Cauerstr 3 D-91058 Erlangen Germany|Friedrich Alexander Univ Erlangen Nurnberg Interdisciplinary Ctr Nanostruct Films Cauerstr 3 D-91058 Erlangen Germany;

Friedrich Alexander Univ Erlangen Nurnberg Inst Phys Kondensierten Mat Staudtstr 3 D-91058 Erlangen Germany|Friedrich Alexander Univ Erlangen Nurnberg Ctr Nanoanal & Electron Microscopy Cauerstr 3 D-91058 Erlangen Germany|Friedrich Alexander Univ Erlangen Nurnberg Interdisciplinary Ctr Nanostruct Films Cauerstr 3 D-91058 Erlangen Germany;

Friedrich Alexander Univ Erlangen Nurnberg Inst Phys Kondensierten Mat Staudtstr 3 D-91058 Erlangen Germany|Friedrich Alexander Univ Erlangen Nurnberg Ctr Nanoanal & Electron Microscopy Cauerstr 3 D-91058 Erlangen Germany|Friedrich Alexander Univ Erlangen Nurnberg Interdisciplinary Ctr Nanostruct Films Cauerstr 3 D-91058 Erlangen Germany;

Friedrich Alexander Univ Erlangen Nurnberg Ctr Nanoanal & Electron Microscopy Cauerstr 3 D-91058 Erlangen Germany|Friedrich Alexander Univ Erlangen Nurnberg Interdisciplinary Ctr Nanostruct Films Cauerstr 3 D-91058 Erlangen Germany|Friedrich Alexander Univ Erlangen Nurnberg Inst Micro & Nanostruct Res Dept Mat Sci & Engn Cauerstr 6 D-91058 Erlangen Germany;

Friedrich Alexander Univ Erlangen Nurnberg Ctr Nanoanal & Electron Microscopy Cauerstr 3 D-91058 Erlangen Germany|Friedrich Alexander Univ Erlangen Nurnberg Interdisciplinary Ctr Nanostruct Films Cauerstr 3 D-91058 Erlangen Germany|Friedrich Alexander Univ Erlangen Nurnberg Inst Micro & Nanostruct Res Dept Mat Sci & Engn Cauerstr 6 D-91058 Erlangen Germany;

Friedrich Alexander Univ Erlangen Nurnberg Ctr Nanoanal & Electron Microscopy Cauerstr 3 D-91058 Erlangen Germany|Friedrich Alexander Univ Erlangen Nurnberg Interdisciplinary Ctr Nanostruct Films Cauerstr 3 D-91058 Erlangen Germany|Friedrich Alexander Univ Erlangen Nurnberg Inst Micro & Nanostruct Res Dept Mat Sci & Engn Cauerstr 6 D-91058 Erlangen Germany;

Friedrich Alexander Univ Erlangen Nurnberg Inst Mat Elect & Energy Technol Dept Mat Sci & Engn Martensstr 7 D-91058 Erlangen Germany;

Friedrich Alexander Univ Erlangen Nurnberg Inst Mat Elect & Energy Technol Dept Mat Sci & Engn Martensstr 7 D-91058 Erlangen Germany;

Friedrich Alexander Univ Erlangen Nurnberg Inst Mat Elect & Energy Technol Dept Mat Sci & Engn Martensstr 7 D-91058 Erlangen Germany;

Friedrich Alexander Univ Erlangen Nurnberg Inst Mat Elect & Energy Technol Dept Mat Sci & Engn Martensstr 7 D-91058 Erlangen Germany;

Friedrich Alexander Univ Erlangen Nurnberg Inst Mat Elect & Energy Technol Dept Mat Sci & Engn Martensstr 7 D-91058 Erlangen Germany;

Polish Acad Sci Inst Phys Aleja Lotnikow 32-46 PL-02668 Warsaw Poland|Int Res Ctr MagTop Aleja Lotnikow 32-46 PL-02668 Warsaw Poland|Natl Tech Univ KhPI Kyrpychova Str 2 UA-61002 Kharkiv Ukraine;

Polish Acad Sci Inst Phys Aleja Lotnikow 32-46 PL-02668 Warsaw Poland|Int Res Ctr MagTop Aleja Lotnikow 32-46 PL-02668 Warsaw Poland;

Polish Acad Sci Inst Phys Aleja Lotnikow 32-46 PL-02668 Warsaw Poland|Int Res Ctr MagTop Aleja Lotnikow 32-46 PL-02668 Warsaw Poland;

Polish Acad Sci Inst Phys Aleja Lotnikow 32-46 PL-02668 Warsaw Poland|Int Res Ctr MagTop Aleja Lotnikow 32-46 PL-02668 Warsaw Poland;

Johannes Kepler Univ Linz Inst Semicond & Solid State Phys A-4040 Linz Austria|E E Elekt GesmbH Langwiesen 7 A-4209 Engerwitzdorf Austria;

Johannes Kepler Univ Linz Inst Semicond & Solid State Phys A-4040 Linz Austria;

Friedrich Alexander Univ Erlangen Nurnberg Lehrstuhl Phys Chem 2 Egerlandstr 3 D-91058 Erlangen Germany;

Friedrich Alexander Univ Erlangen Nurnberg Lehrstuhl Phys Chem 2 Egerlandstr 3 D-91058 Erlangen Germany;

Dept Phys Chair Expt Phys Staudtstr 7 D-91058 Erlangen Germany;

Dept Phys Chair Expt Phys Staudtstr 7 D-91058 Erlangen Germany|Tech Univ Berlin Inst Solid State Phys Hardenbergstr 36 D-10623 Berlin Germany;

Dept Phys Chair Expt Phys Staudtstr 7 D-91058 Erlangen Germany;

Univ Toronto Scarborough Dept Phys & Environm Sci Clean Energy Lab Toronto ON M1C 14A Canada;

Univ Toronto Scarborough Dept Phys & Environm Sci Clean Energy Lab Toronto ON M1C 14A Canada;

Friedrich Alexander Univ Erlangen Nurnberg Dept Mat Sci & Engn Inst Mat Elect & Energy Technol Energy Campus Nurnberg Furtherstr 250 D-90429 Nurnberg Germany;

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epitaxial growth; inkjet printing; metal-halide-perovskites; single-crystal-microstructures;

机译：外延生长;喷墨印刷;金属 - 卤化物 - 钙钛矿;单晶微结构;

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1. Inkjet Printing Epitaxial Metal Halide Perovskites on Various Substrates? [J] . Lu Chaojing, Sun Shiduo, Duo Yiwei Advanced Functional Materials . 2021,第27期

机译：喷墨印刷外延金属卤化物钙锌矿在各种基材上？
2. Pushing PbS/Metal-Halide-Perovskite Core/Epitaxial-Ligand-Shell Nanocrystal Photodetectors beyond 3 μm Wavelength [J] . Killilea Niall, Wu Mingjian, Sytnyk Mykhailo, Advanced Functional Materials . 2019,第14期

机译：推动PbS /金属卤化物钙钛矿核/外延配体壳纳米晶体光电探测器的波长超过3μm
3. Flexible organo-metal halide perovskite solar cells on a Ti metal substrate [J] . Lee Minoh, Jo Yimhyun, Kim Dong Suk, Journal of Materials Chemistry, A. Materials for energy and sustainability . 2015,第8期

机译：Ti金属基板上的柔性有机金属卤化物钙钛矿太阳能电池
4. The Effect of Titanium Oxide Substrate on the Film Morphology and Photoluminescence Properties of Organometal Halide Perovskites [C] . Zhihua Xu, Zhengtao Chen Materials Research Society symposium . 2016

机译：氧化钛基材对有机卤化物膜形态学和光致发光性质的影响
5. Controllable Epitaxial Growth of Metal Halide Perovskites for Single-Crystal Devices [D] . Chen, Yimu. 2020

机译：用于单晶装置的金属卤化物钙锌矿的可控外延生长
6. Efficient metal halide perovskite light-emitting diodes with significantly improved light extraction on nanophotonic substrates [O] . Qianpeng Zhang, Mohammad Mahdi Tavakoli, Leilei Gu, -1

机译：高效的金属卤化物钙钛矿发光二极管在纳米光子衬底上的光提取显着改善
7. Epitaxial Metal Halide Perovskites by Inkjet‐Printing on Various Substrates [O] . Mykhailo Sytnyk, Amir‐Abbas Yousefi‐Amin, Tim Freund, 2020

机译：通过喷墨印刷在各种基材上的外延金属卤化物钙锌矿

Epitaxial Metal Halide Perovskites by Inkjet-Printing on Various Substrates

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