剖析水的氢键网络：电荷转移与核量子效应。

Dissecting the hydrogen bond network of water: Charge transfer and nuclear quantum effects.

作者信息

Flór Mischa, Wilkins David M, de la Puente Miguel, Laage Damien, Cassone Giuseppe, Hassanali Ali, Roke Sylvie

机构信息

Laboratory for Fundamental BioPhotonics (LBP), Institute of Bioengineering (IBI), and Institute of Materials Science (IMX), School of Engineering (STI), and Lausanne Centre for Ultrafast Science (LACUS), École Polytechnique Fédérale de Lausanne (EPFL), Lausanne, Switzerland.

Centre for Quantum Materials and Technologies, School of Mathematics and Physics, Queen's University Belfast, Belfast, Northern Ireland, UK.

出版信息

Science. 2024 Dec 6;386(6726):eads4369. doi: 10.1126/science.ads4369.

DOI:10.1126/science.ads4369

PMID:39446897

Abstract

The molecular structure of water is dynamic, with intermolecular hydrogen (H) bond interactions being modified by both electronic charge transfer and nuclear quantum effects (NQEs). Electronic charge transfer and NQEs potentially change under acidic or basic conditions, but such details have not been measured. In this work, we developed correlated vibrational spectroscopy, a symmetry-based method that separates interacting from noninteracting molecules in self- and cross-correlation spectra, giving access to previously inaccessible information. We found that hydroxide (OH) donated ~8% more negative charge to the H bond network of water, and hydronium (HO) accepted ~4% less negative charge from the H bond network of water. Deuterium oxide (DO) had ~9% more H bonds compared with water (HO), and acidic solutions displayed more dominant NQEs than basic ones.

摘要

水的分子结构是动态的，分子间氢键相互作用会因电荷转移和核量子效应（NQEs）而发生改变。在酸性或碱性条件下，电荷转移和核量子效应可能会发生变化，但此类细节尚未被测量。在这项工作中，我们开发了相关振动光谱法，这是一种基于对称性的方法，可在自相关和互相关光谱中分离相互作用分子与非相互作用分子，从而获取以前无法获得的信息。我们发现，氢氧根（OH）向水的氢键网络提供的负电荷多出约8%，而水合氢离子（H₃O⁺）从水的氢键网络接受的负电荷少了约4%。与水（H₂O）相比，重水（D₂O）的氢键多出约9%，并且酸性溶液中的核量子效应比碱性溶液中更为显著。

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剖析水的氢键网络：电荷转移与核量子效应。

Dissecting the hydrogen bond network of water: Charge transfer and nuclear quantum effects.

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