疏水纳米限域中的核量子效应

Nuclear Quantum Effects in Hydrophobic Nanoconfinement.

作者信息

Shrestha Buddha Ratna, Pillai Sreekiran, Santana Adriano, Donaldson Stephen H, Pascal Tod A, Mishra Himanshu

机构信息

King Abdullah University of Science and Technology (KAUST) , Water Desalination and Reuse Center (WDRC), Biological and Environmental Sciences and Engineering (BESE) Division , Thuwal 23955-6900 , Saudi Arabia.

Département de Physique , Ecole Normale Supérieure/PSL Research University, CNRS , 24 rue Lhomond , 75005 Paris , France.

出版信息

J Phys Chem Lett. 2019 Sep 19;10(18):5530-5535. doi: 10.1021/acs.jpclett.9b01835. Epub 2019 Sep 6.

DOI:10.1021/acs.jpclett.9b01835

PMID:31365261

Abstract

Nuclear quantum effects (NQEs) in water arise due to delocalization, zero-point energy (ZPE), and quantum tunneling of protons. Whereas quantum tunneling is significant only at low temperatures, proton delocalization and ZPE influence the properties of water at normal temperature and pressure (NTP), giving rise to isotope effects. However, the consequences of NQEs for interfaces of water with hydrophobic media, such as perfluorocarbons, have remained largely unexplored. Here, we reveal the existence and signature of NQEs modulating hydrophobic surface forces at NTP. Our experiments demonstrate that the attractive hydrophobic forces between molecularly smooth and rigid perfluorinated surfaces in nanoconfinement are ≈10% higher in HO than in DO, even though the contact angles of HO and DO on these surfaces are indistinguishable. Our molecular dynamics simulations show that the underlying cause of the difference includes the destabilizing effect of ZPE on the librational motions of interfacial HO, which experiences larger quantum effects than DO.

摘要

水中的核量子效应（NQEs）源于质子的离域、零点能（ZPE）和量子隧穿。虽然量子隧穿仅在低温下显著，但质子离域和ZPE会影响水在常温常压（NTP）下的性质，从而产生同位素效应。然而，NQEs对水与疏水性介质（如全氟碳化合物）界面的影响在很大程度上仍未得到探索。在此，我们揭示了在NTP下调节疏水表面力的NQEs的存在及其特征。我们的实验表明，在纳米限域中，分子光滑且刚性的全氟表面之间的吸引性疏水作用力在H₂O中比在D₂O中约高10%，尽管H₂O和D₂O在这些表面上的接触角难以区分。我们的分子动力学模拟表明，这种差异的根本原因包括ZPE对界面H₂O旋转运动的去稳定作用，H₂O比D₂O经历更大的量子效应。

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疏水纳米限域中的核量子效应

Nuclear Quantum Effects in Hydrophobic Nanoconfinement.

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