Molecular engineering of organic–inorganic hybrid perovskites quantum wells

• Published in: Nature chemistry Vol. 11; no. 12; pp. 1151 - 1157
• Main Authors: Gao, Yao, Shi, Enzheng, Deng, Shibin, Shiring, Stephen B., Snaider, Jordan M., Liang, Chao, Yuan, Biao, Song, Ruyi, Janke, Svenja M., Liebman-Peláez, Alexander, Yoo, Pilsun, Zeller, Matthias, Boudouris, Bryan W., Liao, Peilin, Zhu, Chenhui, Blum, Volker, Yu, Yi, Savoie, Brett M., Huang, Libai, Dou, Letian
• Format: Journal Article
• Language: English
• Published: London Nature Publishing Group UK 01.12.2019; Springer Nature; Nature Publishing Group
• Subjects: 639/638/298/917; 639/925/357/1018; 639/925/357/404; Analytical Chemistry; Biochemistry; Charge transfer; Chemical composition; Chemistry; Chemistry and Materials Science; Chemistry, Multidisciplinary; Chemistry/Food Science; Dimensional stability; Electronic structure; Energy charge; Epitaxial growth; Hydrophobicity; Inorganic Chemistry; Interlayers; Optical properties; Optoelectronics; Organic Chemistry; Perovskites; Physical Chemistry; Physical Sciences; Quantum wells; Science & Technology; Superlattices; Thickness; Unit cell; HALIDES; OPTICAL-PROPERTIES; SYSTEMS; CHROMOPHORE; CATION; AMMONIUM
• ISSN: 1755-4330; 1755-4349
• DOI: 10.1038/s41557-019-0354-2

Semiconductor quantum-well structures and superlattices are key building blocks in modern optoelectronics, but it is difficult to simultaneously realize defect-free epitaxial growth while fine tuning the chemical composition, layer thickness and band structure of each layer to achieve the desired performance. Here we demonstrate the modulation of the electronic structure—and consequently the optical properties—of organic semiconducting building blocks that are incorporated between the layers of perovskites through a facile solution processing step. Self-aggregation of the conjugated organic molecules is suppressed by functionalization with sterically demanding groups and single crystalline organic–perovskite hybrid quantum wells (down to one-unit-cell thick) are obtained. The energy and charge transfers between adjacent organic and inorganic layers are shown to be fast and efficient, owing to the atomically flat interface and ultrasmall interlayer distance of the perovskite materials. The resulting two-dimensional hybrid perovskites are very stable due to protection given by the bulky hydrophobic organic groups. A solution-processing step has been used to prepare quantum-well structures that comprise a thin layer of perovskite sandwiched between two layers of conjugated oligothiophene derivatives. The band gap of the resulting 2D hybrid perovskites can be fine-tuned by functionalizing the organic component, which also improves the stability of the system.