Ligand-induced self-assembly of twisted two-dimensional halide perovskites

Jonghee Yang; Addis S. Fuhr; Subeom Shin; Kevin M. Roccapriore; Bogdan Dryzhakov; Bin Hu; Byeongjoo Kang; Hyungju Ahn; Woojae Kim; Bobby Sumpter; Sergei V. Kalinin; Mahshid Ahmadi

doi:10.1038/s44160-025-00780-0

Ligand-induced self-assembly of twisted two-dimensional halide perovskites

Jonghee Yang, Addis S. Fuhr, Subeom Shin, Kevin M. Roccapriore, Bogdan Dryzhakov, Bin Hu, Byeongjoo Kang, Hyungju Ahn, Woojae Kim, Bobby Sumpter, Sergei V. Kalinin, Mahshid Ahmadi

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Abstract

Two-dimensional (2D) halide perovskites (HPs) exhibit intriguing optoelectronic functionalities. Conventionally, 2D HPs have been synthesized with linear and planar molecular spacers, resulting in nominal modifications of their optoelectronic properties. In contrast, lower-dimensional HPs (0D and 1D) have proved accommodating to the incorporation of bulky molecular spacers. Fundamental insights into the incorporation of bulky molecular spacers in 2D HP structures remains elusive. Here, by implementing a high-throughput autonomous exploration workflow, the crystallization behaviours of 2D HPs based on a bulky 3,3-diphenylpropylammonium (DPA) spacer are comprehensively explored. Counterintuitive to conventional HP chemistry, synthesis of 2D DPA₂PbI₄ HPs is indeed feasible when the steric hindrance is mediated by minute incorporation of 3D HP precursors. Furthermore, a moiré superlattice is observed from the DPA₂PbI₄ flakes, indicating the spontaneous formation of twisted stacks of 2D HPs. We hypothesize that the unconventional van der Waals surface of DPA₂PbI₄ facilitates the self-assembly of the twisted stacks of 2D HPs. This work exemplifies how high-throughput experimentation can discover unconventional material systems in which the synthetic principle lies beyond conventional chemical intuition. Furthermore, these findings provide hints for how to chemically manipulate the twist stacking in 2D HPs, thus rendering a straightforward way for bespoke realization of functionalities in exotic materials systems via a bottom-up approach. (Figure presented.)

Original language	English
Article number	2302337
Journal	Nature Synthesis
DOIs	https://doi.org/10.1038/s44160-025-00780-0
State	Accepted/In press - 2025

Funding

J.Y. and M.A. acknowledge support from the National Science Foundation (NSF), award number 2043205, and the Alfred P. Sloan Foundation, award number FG-2022-18275. This research was supported by the Yonsei University Research Fund (2024-22-0106). This research was also supported by a Global\u2013Learning & Academic Research Institution for Master\u2019s\u2013PhD students, and Postdocs (LAMP) Program of the National Research Foundation of Korea (NRF) grant funded by the Ministry of Education (number RS-2024-00442483). Electronic structure calculations and microscopy were performed at the Center for Nanophase Materials Sciences, a US Department of Energy Office of Science User Facility operated at Oak Ridge National Laboratory. B.D. acknowledges support from the US Department of Homeland Security under grant number 16DNARI00018-04-0. Raman spectroscopy instrumentation was supported by DURIP funding (FA9550-18-1-0472) at the Institute of Advanced Materials and Manufacturing at the University of Tennessee. S.V.K. acknowledges support from the US Department of Energy, Office of Science, Office of Basic Energy Sciences, as part of the Energy Frontier 51 Research Centers program the Center for the Science of Synthesis Across Scales under award no. DE-SC0019288, located at University of Washington, DC.

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title = "Ligand-induced self-assembly of twisted two-dimensional halide perovskites",

abstract = "Two-dimensional (2D) halide perovskites (HPs) exhibit intriguing optoelectronic functionalities. Conventionally, 2D HPs have been synthesized with linear and planar molecular spacers, resulting in nominal modifications of their optoelectronic properties. In contrast, lower-dimensional HPs (0D and 1D) have proved accommodating to the incorporation of bulky molecular spacers. Fundamental insights into the incorporation of bulky molecular spacers in 2D HP structures remains elusive. Here, by implementing a high-throughput autonomous exploration workflow, the crystallization behaviours of 2D HPs based on a bulky 3,3-diphenylpropylammonium (DPA) spacer are comprehensively explored. Counterintuitive to conventional HP chemistry, synthesis of 2D DPA2PbI4 HPs is indeed feasible when the steric hindrance is mediated by minute incorporation of 3D HP precursors. Furthermore, a moir{\'e} superlattice is observed from the DPA2PbI4 flakes, indicating the spontaneous formation of twisted stacks of 2D HPs. We hypothesize that the unconventional van der Waals surface of DPA2PbI4 facilitates the self-assembly of the twisted stacks of 2D HPs. This work exemplifies how high-throughput experimentation can discover unconventional material systems in which the synthetic principle lies beyond conventional chemical intuition. Furthermore, these findings provide hints for how to chemically manipulate the twist stacking in 2D HPs, thus rendering a straightforward way for bespoke realization of functionalities in exotic materials systems via a bottom-up approach. (Figure presented.)",

author = "Jonghee Yang and Fuhr, {Addis S.} and Subeom Shin and Roccapriore, {Kevin M.} and Bogdan Dryzhakov and Bin Hu and Byeongjoo Kang and Hyungju Ahn and Woojae Kim and Bobby Sumpter and Kalinin, {Sergei V.} and Mahshid Ahmadi",

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doi = "10.1038/s44160-025-00780-0",

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AU - Fuhr, Addis S.

AU - Shin, Subeom

AU - Roccapriore, Kevin M.

AU - Dryzhakov, Bogdan

AU - Hu, Bin

AU - Kang, Byeongjoo

AU - Ahn, Hyungju

AU - Kim, Woojae

AU - Sumpter, Bobby

AU - Kalinin, Sergei V.

AU - Ahmadi, Mahshid

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AB - Two-dimensional (2D) halide perovskites (HPs) exhibit intriguing optoelectronic functionalities. Conventionally, 2D HPs have been synthesized with linear and planar molecular spacers, resulting in nominal modifications of their optoelectronic properties. In contrast, lower-dimensional HPs (0D and 1D) have proved accommodating to the incorporation of bulky molecular spacers. Fundamental insights into the incorporation of bulky molecular spacers in 2D HP structures remains elusive. Here, by implementing a high-throughput autonomous exploration workflow, the crystallization behaviours of 2D HPs based on a bulky 3,3-diphenylpropylammonium (DPA) spacer are comprehensively explored. Counterintuitive to conventional HP chemistry, synthesis of 2D DPA2PbI4 HPs is indeed feasible when the steric hindrance is mediated by minute incorporation of 3D HP precursors. Furthermore, a moiré superlattice is observed from the DPA2PbI4 flakes, indicating the spontaneous formation of twisted stacks of 2D HPs. We hypothesize that the unconventional van der Waals surface of DPA2PbI4 facilitates the self-assembly of the twisted stacks of 2D HPs. This work exemplifies how high-throughput experimentation can discover unconventional material systems in which the synthetic principle lies beyond conventional chemical intuition. Furthermore, these findings provide hints for how to chemically manipulate the twist stacking in 2D HPs, thus rendering a straightforward way for bespoke realization of functionalities in exotic materials systems via a bottom-up approach. (Figure presented.)

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Ligand-induced self-assembly of twisted two-dimensional halide perovskites

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