Unveiling high-mobility hot carriers in a two-dimensional conjugated coordination polymer

Shuai Fu; Xing Huang; Guoquan Gao; Petko St. Petkov; Wenpei Gao; Jianjun Zhang; Lei Gao; Heng Zhang; Min Liu; Mike Hambsch; Wenjie Zhang; Jiaxu Zhang; Keming Li; Ute Kaiser; Stuart S.P. Parkin; Stefan C.B. Mannsfeld; Tong Zhu; Hai I. Wang; Zhiyong Wang; Renhao Dong; Xinliang Feng; Mischa Bonn

doi:10.1038/s41563-025-02246-2

Unveiling high-mobility hot carriers in a two-dimensional conjugated coordination polymer

Shuai Fu, Xing Huang, Guoquan Gao, Petko St. Petkov, Wenpei Gao, Jianjun Zhang, Lei Gao, Heng Zhang, Min Liu, Mike Hambsch, Wenjie Zhang, Jiaxu Zhang, Keming Li, Ute Kaiser, Stuart S.P. Parkin, Stefan C.B. Mannsfeld, Tong Zhu^*, Hai I. Wang^*, Zhiyong Wang^*, Renhao Dong^*Xinliang Feng^*, Mischa Bonn^*

^*Corresponding author for this work

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

Abstract

Hot carriers, inheriting excess kinetic energy from high-energy photons, drive numerous optoelectronic applications reliant on non-equilibrium transport processes. Although extensively studied in inorganic materials, their potential in organic-based systems remains largely unexplored. Here we demonstrate highly mobile hot carriers in crystalline two-dimensional conjugated coordination polymer Cu₃BHT (BHT, benzenehexathiol) films. Leveraging a suite of ultrafast spectroscopic and imaging techniques, we map the microscopic charge transport landscape in Cu₃BHT films following non-equilibrium photoexcitation across temporal, spatial and frequency domains, revealing two distinct high-mobility transport regimes. In the non-equilibrium regime, hot carriers achieve an ultrahigh mobility of ~2,000 cm² V^–1 s^–1, traversing grain boundaries up to ~300 nm within a picosecond. In the quasi-equilibrium regime, free carriers exhibit Drude-type, band-like transport with a remarkable mobility of ~400 cm² V^–1 s^–1 and an intrinsic diffusion length exceeding 1 μm. These findings position two-dimensional conjugated coordination polymers as versatile platforms for advancing organic-based hot carrier applications.

Original language	English
Article number	12174
Journal	Nature Materials
DOIs	https://doi.org/10.1038/s41563-025-02246-2
Publication status	Accepted/In press - 2025
Externally published	Yes

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Fu, S., Huang, X., Gao, G., St. Petkov, P., Gao, W., Zhang, J., Gao, L., Zhang, H., Liu, M., Hambsch, M., Zhang, W., Zhang, J., Li, K., Kaiser, U., Parkin, S. S. P., Mannsfeld, S. C. B., Zhu, T., Wang, H. I., Wang, Z., ... Bonn, M. (Accepted/In press). Unveiling high-mobility hot carriers in a two-dimensional conjugated coordination polymer. Nature Materials, Article 12174. https://doi.org/10.1038/s41563-025-02246-2

@article{55d43c9518f246a88c02f9fdc78207fc,

title = "Unveiling high-mobility hot carriers in a two-dimensional conjugated coordination polymer",

abstract = "Hot carriers, inheriting excess kinetic energy from high-energy photons, drive numerous optoelectronic applications reliant on non-equilibrium transport processes. Although extensively studied in inorganic materials, their potential in organic-based systems remains largely unexplored. Here we demonstrate highly mobile hot carriers in crystalline two-dimensional conjugated coordination polymer Cu3BHT (BHT, benzenehexathiol) films. Leveraging a suite of ultrafast spectroscopic and imaging techniques, we map the microscopic charge transport landscape in Cu3BHT films following non-equilibrium photoexcitation across temporal, spatial and frequency domains, revealing two distinct high-mobility transport regimes. In the non-equilibrium regime, hot carriers achieve an ultrahigh mobility of ~2,000 cm2 V–1 s–1, traversing grain boundaries up to ~300 nm within a picosecond. In the quasi-equilibrium regime, free carriers exhibit Drude-type, band-like transport with a remarkable mobility of ~400 cm2 V–1 s–1 and an intrinsic diffusion length exceeding 1 μm. These findings position two-dimensional conjugated coordination polymers as versatile platforms for advancing organic-based hot carrier applications.",

author = "Shuai Fu and Xing Huang and Guoquan Gao and {St. Petkov}, Petko and Wenpei Gao and Jianjun Zhang and Lei Gao and Heng Zhang and Min Liu and Mike Hambsch and Wenjie Zhang and Jiaxu Zhang and Keming Li and Ute Kaiser and Parkin, {Stuart S.P.} and Mannsfeld, {Stefan C.B.} and Tong Zhu and Wang, {Hai I.} and Zhiyong Wang and Renhao Dong and Xinliang Feng and Mischa Bonn",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2025.",

year = "2025",

doi = "10.1038/s41563-025-02246-2",

language = "English",

journal = "Nature Materials",

issn = "1476-1122",

publisher = "Nature Publishing Group",

}

Fu, S, Huang, X, Gao, G, St. Petkov, P, Gao, W, Zhang, J, Gao, L, Zhang, H, Liu, M, Hambsch, M, Zhang, W, Zhang, J, Li, K, Kaiser, U, Parkin, SSP, Mannsfeld, SCB, Zhu, T, Wang, HI, Wang, Z, Dong, R, Feng, X & Bonn, M 2025, 'Unveiling high-mobility hot carriers in a two-dimensional conjugated coordination polymer', Nature Materials. https://doi.org/10.1038/s41563-025-02246-2

TY - JOUR

T1 - Unveiling high-mobility hot carriers in a two-dimensional conjugated coordination polymer

AU - Fu, Shuai

AU - Huang, Xing

AU - Gao, Guoquan

AU - St. Petkov, Petko

AU - Gao, Wenpei

AU - Zhang, Jianjun

AU - Gao, Lei

AU - Zhang, Heng

AU - Liu, Min

AU - Hambsch, Mike

AU - Zhang, Wenjie

AU - Zhang, Jiaxu

AU - Li, Keming

AU - Kaiser, Ute

AU - Parkin, Stuart S.P.

AU - Mannsfeld, Stefan C.B.

AU - Zhu, Tong

AU - Wang, Hai I.

AU - Wang, Zhiyong

AU - Dong, Renhao

AU - Feng, Xinliang

AU - Bonn, Mischa

PY - 2025

Y1 - 2025

N2 - Hot carriers, inheriting excess kinetic energy from high-energy photons, drive numerous optoelectronic applications reliant on non-equilibrium transport processes. Although extensively studied in inorganic materials, their potential in organic-based systems remains largely unexplored. Here we demonstrate highly mobile hot carriers in crystalline two-dimensional conjugated coordination polymer Cu3BHT (BHT, benzenehexathiol) films. Leveraging a suite of ultrafast spectroscopic and imaging techniques, we map the microscopic charge transport landscape in Cu3BHT films following non-equilibrium photoexcitation across temporal, spatial and frequency domains, revealing two distinct high-mobility transport regimes. In the non-equilibrium regime, hot carriers achieve an ultrahigh mobility of ~2,000 cm2 V–1 s–1, traversing grain boundaries up to ~300 nm within a picosecond. In the quasi-equilibrium regime, free carriers exhibit Drude-type, band-like transport with a remarkable mobility of ~400 cm2 V–1 s–1 and an intrinsic diffusion length exceeding 1 μm. These findings position two-dimensional conjugated coordination polymers as versatile platforms for advancing organic-based hot carrier applications.

AB - Hot carriers, inheriting excess kinetic energy from high-energy photons, drive numerous optoelectronic applications reliant on non-equilibrium transport processes. Although extensively studied in inorganic materials, their potential in organic-based systems remains largely unexplored. Here we demonstrate highly mobile hot carriers in crystalline two-dimensional conjugated coordination polymer Cu3BHT (BHT, benzenehexathiol) films. Leveraging a suite of ultrafast spectroscopic and imaging techniques, we map the microscopic charge transport landscape in Cu3BHT films following non-equilibrium photoexcitation across temporal, spatial and frequency domains, revealing two distinct high-mobility transport regimes. In the non-equilibrium regime, hot carriers achieve an ultrahigh mobility of ~2,000 cm2 V–1 s–1, traversing grain boundaries up to ~300 nm within a picosecond. In the quasi-equilibrium regime, free carriers exhibit Drude-type, band-like transport with a remarkable mobility of ~400 cm2 V–1 s–1 and an intrinsic diffusion length exceeding 1 μm. These findings position two-dimensional conjugated coordination polymers as versatile platforms for advancing organic-based hot carrier applications.

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U2 - 10.1038/s41563-025-02246-2

DO - 10.1038/s41563-025-02246-2

M3 - Article

AN - SCOPUS:105005408408

SN - 1476-1122

JO - Nature Materials

JF - Nature Materials

M1 - 12174

ER -

Unveiling high-mobility hot carriers in a two-dimensional conjugated coordination polymer

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