Blue organic long-persistent luminescence via upconversion from charge-transfer to locally excited singlet state

Zesen Lin; Jinting Ye; Shin Shinohara; Yuya Tanaka; Rengo Yoshioka; Chin Yiu Chan; Yi Ting Lee; Xun Tang; Kirill Mitrofanov; Kai Wang; Hayato Ouchi; Liliia Moshniaha; Yemineni S.L.V. Narayana; Hisao Ishii; Xiao Hong Zhang; Chihaya Adachi; Xian Kai Chen; Ryota Kabe

doi:10.1038/s41467-025-58048-2

Blue organic long-persistent luminescence via upconversion from charge-transfer to locally excited singlet state

Zesen Lin, Jinting Ye, Shin Shinohara, Yuya Tanaka, Rengo Yoshioka, Chin Yiu Chan, Yi Ting Lee, Xun Tang, Kirill Mitrofanov, Kai Wang, Hayato Ouchi, Liliia Moshniaha, Yemineni S.L.V. Narayana, Hisao Ishii, Xiao Hong Zhang, Chihaya Adachi, Xian Kai Chen, Ryota Kabe

Functional Materials Chemistry

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

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Abstract

Long-persistent luminescence (LPL) materials have applications from safety signage to bioimaging; however, existing organic LPL (OLPL) systems do not align with human scotopic vision, which is sensitive to blue light. We present a strategy to blueshift the emissions in binary OLPL systems by upconverting the charge-transfer (CT) to a locally excited (LE) singlet state. Through rigorous steady-state and time-resolved photoluminescence spectroscopy and wavelength-resolved thermoluminescence measurements, we provide the direct experimental evidence for this upconversion in OLPL systems featuring small energy offsets between the lowest-energy CT and LE singlet states. These systems exhibited strong room temperature LPL, particularly when extrinsic electron traps are added. Importantly, the developed OLPL system achieved Class A (ISO 17398) LPL, matching well with human scotopic vision. The findings not only elucidate the role of small energy offsets in modulating LPL but also provide potential avenues for enhancing the efficiency and applicability of OLPL materials.

Original language	English
Article number	2686
Journal	Nature communications
Volume	16
Issue number	1
DOIs	https://doi.org/10.1038/s41467-025-58048-2
Publication status	Published - Dec 2025

All Science Journal Classification (ASJC) codes

General Chemistry
General Biochemistry,Genetics and Molecular Biology
General Physics and Astronomy

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Lin, Z., Ye, J., Shinohara, S., Tanaka, Y., Yoshioka, R., Chan, C. Y., Lee, Y. T., Tang, X., Mitrofanov, K., Wang, K., Ouchi, H., Moshniaha, L., Narayana, Y. S. L. V., Ishii, H., Zhang, X. H., Adachi, C., Chen, X. K., & Kabe, R. (2025). Blue organic long-persistent luminescence via upconversion from charge-transfer to locally excited singlet state. Nature communications, 16(1), Article 2686. https://doi.org/10.1038/s41467-025-58048-2

Lin, Z, Ye, J, Shinohara, S, Tanaka, Y, Yoshioka, R, Chan, CY, Lee, YT, Tang, X, Mitrofanov, K, Wang, K, Ouchi, H, Moshniaha, L, Narayana, YSLV, Ishii, H, Zhang, XH, Adachi, C, Chen, XK & Kabe, R 2025, 'Blue organic long-persistent luminescence via upconversion from charge-transfer to locally excited singlet state', Nature communications, vol. 16, no. 1, 2686. https://doi.org/10.1038/s41467-025-58048-2

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title = "Blue organic long-persistent luminescence via upconversion from charge-transfer to locally excited singlet state",

abstract = "Long-persistent luminescence (LPL) materials have applications from safety signage to bioimaging; however, existing organic LPL (OLPL) systems do not align with human scotopic vision, which is sensitive to blue light. We present a strategy to blueshift the emissions in binary OLPL systems by upconverting the charge-transfer (CT) to a locally excited (LE) singlet state. Through rigorous steady-state and time-resolved photoluminescence spectroscopy and wavelength-resolved thermoluminescence measurements, we provide the direct experimental evidence for this upconversion in OLPL systems featuring small energy offsets between the lowest-energy CT and LE singlet states. These systems exhibited strong room temperature LPL, particularly when extrinsic electron traps are added. Importantly, the developed OLPL system achieved Class A (ISO 17398) LPL, matching well with human scotopic vision. The findings not only elucidate the role of small energy offsets in modulating LPL but also provide potential avenues for enhancing the efficiency and applicability of OLPL materials.",

author = "Zesen Lin and Jinting Ye and Shin Shinohara and Yuya Tanaka and Rengo Yoshioka and Chan, {Chin Yiu} and Lee, {Yi Ting} and Xun Tang and Kirill Mitrofanov and Kai Wang and Hayato Ouchi and Liliia Moshniaha and Narayana, {Yemineni S.L.V.} and Hisao Ishii and Zhang, {Xiao Hong} and Chihaya Adachi and Chen, {Xian Kai} and Ryota Kabe",

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year = "2025",

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doi = "10.1038/s41467-025-58048-2",

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T1 - Blue organic long-persistent luminescence via upconversion from charge-transfer to locally excited singlet state

AU - Lin, Zesen

AU - Ye, Jinting

AU - Shinohara, Shin

AU - Tanaka, Yuya

AU - Yoshioka, Rengo

AU - Chan, Chin Yiu

AU - Lee, Yi Ting

AU - Tang, Xun

AU - Mitrofanov, Kirill

AU - Wang, Kai

AU - Ouchi, Hayato

AU - Moshniaha, Liliia

AU - Narayana, Yemineni S.L.V.

AU - Ishii, Hisao

AU - Zhang, Xiao Hong

AU - Adachi, Chihaya

AU - Chen, Xian Kai

AU - Kabe, Ryota

PY - 2025/12

Y1 - 2025/12

N2 - Long-persistent luminescence (LPL) materials have applications from safety signage to bioimaging; however, existing organic LPL (OLPL) systems do not align with human scotopic vision, which is sensitive to blue light. We present a strategy to blueshift the emissions in binary OLPL systems by upconverting the charge-transfer (CT) to a locally excited (LE) singlet state. Through rigorous steady-state and time-resolved photoluminescence spectroscopy and wavelength-resolved thermoluminescence measurements, we provide the direct experimental evidence for this upconversion in OLPL systems featuring small energy offsets between the lowest-energy CT and LE singlet states. These systems exhibited strong room temperature LPL, particularly when extrinsic electron traps are added. Importantly, the developed OLPL system achieved Class A (ISO 17398) LPL, matching well with human scotopic vision. The findings not only elucidate the role of small energy offsets in modulating LPL but also provide potential avenues for enhancing the efficiency and applicability of OLPL materials.

AB - Long-persistent luminescence (LPL) materials have applications from safety signage to bioimaging; however, existing organic LPL (OLPL) systems do not align with human scotopic vision, which is sensitive to blue light. We present a strategy to blueshift the emissions in binary OLPL systems by upconverting the charge-transfer (CT) to a locally excited (LE) singlet state. Through rigorous steady-state and time-resolved photoluminescence spectroscopy and wavelength-resolved thermoluminescence measurements, we provide the direct experimental evidence for this upconversion in OLPL systems featuring small energy offsets between the lowest-energy CT and LE singlet states. These systems exhibited strong room temperature LPL, particularly when extrinsic electron traps are added. Importantly, the developed OLPL system achieved Class A (ISO 17398) LPL, matching well with human scotopic vision. The findings not only elucidate the role of small energy offsets in modulating LPL but also provide potential avenues for enhancing the efficiency and applicability of OLPL materials.

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Blue organic long-persistent luminescence via upconversion from charge-transfer to locally excited singlet state

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