Asymmetric rotations slow down diffusion under confinement

Zhiqiang Liu; Xun Kan; Mingbin Gao; Yi Ji; Fangxiu Ye; Jingyi Tan; Fengqing Liu; Jiamin Yuan; Xiaomin Tang; Haohan Li; Pan Gao; Jiaao Xue; Qun Cai; Naresh C. Osti; Niina H. Jalarvo; Cheng Li; Yongcun Zou; Yi Li; Shutao Xu; Guangjin Hou; Mao Ye; Fujian Liu; Anmin Zheng

doi:10.1038/s41467-025-57242-6

Asymmetric rotations slow down diffusion under confinement

Zhiqiang Liu, Xun Kan, Mingbin Gao, Yi Ji, Fangxiu Ye, Jingyi Tan, Fengqing Liu, Jiamin Yuan, Xiaomin Tang, Haohan Li, Pan Gao, Jiaao Xue, Qun Cai, Naresh C. Osti, Niina H. Jalarvo, Cheng Li, Yongcun Zou, Yi Li, Shutao Xu, Guangjin HouMao Ye, Fujian Liu, Anmin Zheng

Research output: Contribution to journal › Article › peer-review

Abstract

Translation and rotation are the two most fundamental forms of diffusion, yet their coupling mechanism is not clear, especially under confinement. Here, we provided evidence of the coupling between rotation and translation using a substituted benzene molecule as an example. A counterintuitive behavior was observed where the movement of the smaller molecule with an asymmetric shape was unexpectedly slower than the larger one with a symmetric shape in confined channels of zeolite. We showed that this diffusion behavior was caused by the presence of the specific and selective interaction of the asymmetric guest with the pores, which increased the local restricted residence time, thus inhibiting the translation under confinement, as further confirmed by dynamic breakthrough curves, uptake measurements, quasi-elastic neutron scattering, and ²H solid-state NMR techniques. Our work correlated asymmetric rotation and diffusion under a confined environment, which enriched our understanding of the coupling between rotation and translation and could shed light on a fundamental understanding of the diffusion process.

Original language	English
Article number	2018
Journal	Nature Communications
Volume	16
Issue number	1
DOIs	https://doi.org/10.1038/s41467-025-57242-6
State	Published - Dec 2025

Funding

This work was supported by the National Key R&D Program of China (No. 2022YFE0116000 and 2021YFA1502600), the National Science Foundation of China (No. 22125304, 22202215, 22032005, 22241801, 22293021, 22208337, 22002174, 22022804, 22378064, 22325405, 22432005, and U24A20528), the Natural Science Foundation of Hubei Province (2024AFA054), the Postdoctoral Fellowship Program of CPSF under Grant Number GZB20240764, and the Fundamental Research Funds for the Central Universities (20720240060). Numerical calculation is supported by High-Performance Computing Center of Wuhan University of Science and Technology. A portion of this research used resources at the Spallation Neutron Source, a DOE Office of Science User Facility operated by the Oak Ridge National Laboratory. The beam time was allocated to BASIS on proposal number IPTS-34773. We thank the staffs from the BL06B1 beamline of National Facility at Shanghai Synchrotron Radiation Facility for assistance in data collection of infrared spectroscopy.

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title = "Asymmetric rotations slow down diffusion under confinement",

abstract = "Translation and rotation are the two most fundamental forms of diffusion, yet their coupling mechanism is not clear, especially under confinement. Here, we provided evidence of the coupling between rotation and translation using a substituted benzene molecule as an example. A counterintuitive behavior was observed where the movement of the smaller molecule with an asymmetric shape was unexpectedly slower than the larger one with a symmetric shape in confined channels of zeolite. We showed that this diffusion behavior was caused by the presence of the specific and selective interaction of the asymmetric guest with the pores, which increased the local restricted residence time, thus inhibiting the translation under confinement, as further confirmed by dynamic breakthrough curves, uptake measurements, quasi-elastic neutron scattering, and 2H solid-state NMR techniques. Our work correlated asymmetric rotation and diffusion under a confined environment, which enriched our understanding of the coupling between rotation and translation and could shed light on a fundamental understanding of the diffusion process.",

author = "Zhiqiang Liu and Xun Kan and Mingbin Gao and Yi Ji and Fangxiu Ye and Jingyi Tan and Fengqing Liu and Jiamin Yuan and Xiaomin Tang and Haohan Li and Pan Gao and Jiaao Xue and Qun Cai and Osti, {Naresh C.} and Jalarvo, {Niina H.} and Cheng Li and Yongcun Zou and Yi Li and Shutao Xu and Guangjin Hou and Mao Ye and Fujian Liu and Anmin Zheng",

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doi = "10.1038/s41467-025-57242-6",

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T1 - Asymmetric rotations slow down diffusion under confinement

AU - Liu, Zhiqiang

AU - Kan, Xun

AU - Gao, Mingbin

AU - Ji, Yi

AU - Ye, Fangxiu

AU - Tan, Jingyi

AU - Liu, Fengqing

AU - Yuan, Jiamin

AU - Tang, Xiaomin

AU - Li, Haohan

AU - Gao, Pan

AU - Xue, Jiaao

AU - Cai, Qun

AU - Osti, Naresh C.

AU - Jalarvo, Niina H.

AU - Li, Cheng

AU - Zou, Yongcun

AU - Li, Yi

AU - Xu, Shutao

AU - Hou, Guangjin

AU - Ye, Mao

AU - Liu, Fujian

AU - Zheng, Anmin

PY - 2025/12

Y1 - 2025/12

N2 - Translation and rotation are the two most fundamental forms of diffusion, yet their coupling mechanism is not clear, especially under confinement. Here, we provided evidence of the coupling between rotation and translation using a substituted benzene molecule as an example. A counterintuitive behavior was observed where the movement of the smaller molecule with an asymmetric shape was unexpectedly slower than the larger one with a symmetric shape in confined channels of zeolite. We showed that this diffusion behavior was caused by the presence of the specific and selective interaction of the asymmetric guest with the pores, which increased the local restricted residence time, thus inhibiting the translation under confinement, as further confirmed by dynamic breakthrough curves, uptake measurements, quasi-elastic neutron scattering, and 2H solid-state NMR techniques. Our work correlated asymmetric rotation and diffusion under a confined environment, which enriched our understanding of the coupling between rotation and translation and could shed light on a fundamental understanding of the diffusion process.

AB - Translation and rotation are the two most fundamental forms of diffusion, yet their coupling mechanism is not clear, especially under confinement. Here, we provided evidence of the coupling between rotation and translation using a substituted benzene molecule as an example. A counterintuitive behavior was observed where the movement of the smaller molecule with an asymmetric shape was unexpectedly slower than the larger one with a symmetric shape in confined channels of zeolite. We showed that this diffusion behavior was caused by the presence of the specific and selective interaction of the asymmetric guest with the pores, which increased the local restricted residence time, thus inhibiting the translation under confinement, as further confirmed by dynamic breakthrough curves, uptake measurements, quasi-elastic neutron scattering, and 2H solid-state NMR techniques. Our work correlated asymmetric rotation and diffusion under a confined environment, which enriched our understanding of the coupling between rotation and translation and could shed light on a fundamental understanding of the diffusion process.

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JO - Nature Communications

JF - Nature Communications

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Asymmetric rotations slow down diffusion under confinement

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