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Main Authors: Dai, Chuanwei, Zhao, Yunbiao, Ouyang, Xiao, Huang, Huaqing, Liang, Yulan, Bai, Jiaqi, Song, Yingjie, Sun, Jianhan, Duan, Yiqun, Ma, Wenjun, Huang, Senlin, Wang, Shufeng, Xue, Jianming, Ouyang, Xiaoping
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.26751
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author Dai, Chuanwei
Zhao, Yunbiao
Ouyang, Xiao
Huang, Huaqing
Liang, Yulan
Bai, Jiaqi
Song, Yingjie
Sun, Jianhan
Duan, Yiqun
Ma, Wenjun
Huang, Senlin
Wang, Shufeng
Xue, Jianming
Ouyang, Xiaoping
author_facet Dai, Chuanwei
Zhao, Yunbiao
Ouyang, Xiao
Huang, Huaqing
Liang, Yulan
Bai, Jiaqi
Song, Yingjie
Sun, Jianhan
Duan, Yiqun
Ma, Wenjun
Huang, Senlin
Wang, Shufeng
Xue, Jianming
Ouyang, Xiaoping
contents Ultrafast scintillators are indispensable for precise timing in high-energy physics and medical diagnostics. Fundamentally constrained by the trade-off between emission rate and light yield, conventional scintillators remain kinetically trapped in the sub-nanosecond regime, failing to break 50-picosecond limit. Here, we demonstrate a strategy to bypass this limitation by harnessing the coherent radiative acceleration in weakly confined CsPbCl3 perovskite nanocrystals to generate an ultrafast photon burst. This effect originates from the giant oscillator strength, which we unlock by suppressing exciton-phonon scattering at mild cryogenic temperatures. Consequently, our scintillator achieves an unprecedented dominant lifetime of 13.11 ps alongside a high light yield of 21,851 ph/MeV. The resulting prompt photon emission rate more than 100 times higher than that of state-of-the-art ultrafast scintillators. We validate this breakthrough in realistic detection scenarios, achieving a coincidence time resolution of 30.8 ps and accurately resolving 13.5 ps electron bunches and 16.6 ps single-shot gamma-ray pulses. Our findings establish a robust coherent framework for next-generation ultrafast scintillators, pushing extreme radiation diagnostics into the picosecond frontier.
format Preprint
id arxiv_https___arxiv_org_abs_2604_26751
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Sub-50 Picosecond exceptionally Bright Perovskite Scintillation by Unlocking Giant Oscillator Strength
Dai, Chuanwei
Zhao, Yunbiao
Ouyang, Xiao
Huang, Huaqing
Liang, Yulan
Bai, Jiaqi
Song, Yingjie
Sun, Jianhan
Duan, Yiqun
Ma, Wenjun
Huang, Senlin
Wang, Shufeng
Xue, Jianming
Ouyang, Xiaoping
Mesoscale and Nanoscale Physics
Ultrafast scintillators are indispensable for precise timing in high-energy physics and medical diagnostics. Fundamentally constrained by the trade-off between emission rate and light yield, conventional scintillators remain kinetically trapped in the sub-nanosecond regime, failing to break 50-picosecond limit. Here, we demonstrate a strategy to bypass this limitation by harnessing the coherent radiative acceleration in weakly confined CsPbCl3 perovskite nanocrystals to generate an ultrafast photon burst. This effect originates from the giant oscillator strength, which we unlock by suppressing exciton-phonon scattering at mild cryogenic temperatures. Consequently, our scintillator achieves an unprecedented dominant lifetime of 13.11 ps alongside a high light yield of 21,851 ph/MeV. The resulting prompt photon emission rate more than 100 times higher than that of state-of-the-art ultrafast scintillators. We validate this breakthrough in realistic detection scenarios, achieving a coincidence time resolution of 30.8 ps and accurately resolving 13.5 ps electron bunches and 16.6 ps single-shot gamma-ray pulses. Our findings establish a robust coherent framework for next-generation ultrafast scintillators, pushing extreme radiation diagnostics into the picosecond frontier.
title Sub-50 Picosecond exceptionally Bright Perovskite Scintillation by Unlocking Giant Oscillator Strength
topic Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2604.26751