関西光量子科学研究所 | 【現地開催】第117回KPSIセミナー Capturing Transient Species in Ionized Liquid Water and Aqueous Solutions

 　  関西光量子科学研究所 >> KPSIセミナー >>Capturing Transient Species in Ionized Liquid Water and Aqueous Solutions

セミナー

第117回KPSIセミナー（現地開催）

Capturing Transient Species in Ionized Liquid Water and Aqueous Solutions

南洋理工大学 シンガポール 

　Loh Zhi-Heng  教授

概要（Abstract）

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The ionization of liquid water serves as the principal trigger for a myriad of phenomena that are relevant to radiation chemistry and radiation biology. The earliest events that follow the ionization of water, however, remain relatively unknown. Of particular interest are the lifetime of the transient water radical cation (H₂O·⁺) and the fate of the electron that is injected into the conduction band of water by ionization. Femtosecond soft X-ray free-electron laser probing at the oxygen K edge is employed to track the primary proton transfer reaction of ionized liquid water. The experimental results suggest that H₂O·⁺ undergoes proton transfer to yield vibrationally excited OH· on the timescale of 46 ± 10 fs. Subsequent vibrational relaxation of OH· occurs with a time constant of 0.18 ± 0.02 ps [1]. By employing few-cycle pulses in the visible to near-infrared (500 – 900 nm) and the short-wave infrared (0.9 – 1.7 mm), we have performed a comprehensive probe of the fate of the electron that is initially injected into the conduction band by ionization [2]. The results suggest that the relaxation of the conduction band electron to the hydrated s electron proceeds via an intermediate state, whose lifetime is found to be 62 ± 10 fs (110 ± 5 fs) in H₂O (D₂O), identified as the p electron. Extension of these studies to biomolecules in aqueous solution reveal vibrational wave packet dynamics induced by photoionization or photodetachment [3–8]. Analysis of the wave packet dynamics reveals the normal modes that drive structural reorganization upon electron ejection and lifetimes of transient radical cations. Our results shed light on the elementary ultrafast dynamics that accompany the interaction of ionizing radiation with molecules of biological relevance.

References

[1] Science 367(2017)179.                                      [2] Nat. Commun. 13(2022)7300.

[3] Nat. Commun. 10(2019)2944.                            [4] Phys. Chem. Chem. Phys. 23(2021)18525.

[5] J. Chem. Phys. 155(2021)134306.               　　  [6] Phys. Chem. Chem. Phys. 24(2022)2800.

[7] Phys. Chem. Chem. Phys. 24(2022)12236    　　  [8] J. Phys. Chem. A 128(2024)626.

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