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Paper detail

Quantum tunnelling-integrated optoplasmonic nanotrap enables conductance visualisation of individual proteins

Biological electron transfer (ET) relies on quantum mechanical tunnelling through a dynamically folded protein. Yet, the spatiotemporal coupling between structural fluctuations and electron flux remains poorly understood, largely due to limitations in existing experimental techniques, such as ensemble averaging and non-physiological operating conditions. Here, we introduce a quantum tunnelling-integrated optoplasmonic nanotrap (QTOP-trap), an optoelectronic platform that combines plasmonic optical trapping with real-time quantum tunnelling measurements. This label-free approach enables single-molecule resolution of protein conductance in physiological electrolytes, achieving sub-3 nm spatial precision and 10-μs temporal resolution. By synchronising optoelectronic measurements, QTOP-trap resolves protein-specific conductance signatures and directly correlates tertiary structure dynamics with conductance using a "protein switch" strategy. This methodology establishes a universal framework for dissecting non-equilibrium ET mechanisms in individual conformational-active proteins, with broad implications for bioenergetics research and biomimetic quantum device design.

preprint2026arXivOpen access
Biao-Feng ZengZian WangYuxin YangXufei MaLiang XuYi ShenLong YiYizheng FangYe TianZhenrong ZhengYudong CuiJi CaoGe BaiWeixiang YePan WangCuifang KuangJoshua B. EdelAleksandar P. IvanovXu LiuLonghua Tang
Biological Physics
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Biao-Feng ZengZian WangYuxin YangXufei MaLiang XuYi ShenLong YiYizheng FangYe TianZhenrong ZhengYudong CuiJi CaoGe BaiWeixiang YePan WangCuifang KuangJoshua B. EdelAleksandar P. IvanovXu LiuLonghua Tang

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