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Reorientation of Hydrogen Bonds Renders Unusual Enhancement in Thermal Transport of Water in Nanoconfined Environments

Yuan Gao, Ziqiao Chen, Yue Zhang, Yanwei Wen, Xiaotong Yu, Bin Shan, Baoxing Xu, Rong Chen

2024Nano Letters13 citationsDOI

Abstract

Liquid confined in a nanochannel or nanotube has exhibited a superfast transport phenomenon, providing an ideal heat and mass transfer platform to meet the increasingly stringent challenge of thermal management in developing high-power-density nanoelectronics and nanochips. However, understanding the thermal transport of confined liquid is currently lacking and is speculated to be fundamentally different from that of bulk counterparts due to the unprecedented thermodynamics of liquid in nanoconfined environments. Here, we report that the thermal conductivity of water confined in a silica nanotube is nearly 2-fold as that of bulk status. Further molecular dynamics simulations reveal that this unusual enhancement originates from the densification and reorientation of local hydrogen bonds close to the nanotubes. Thermal-confinement scaling law is established and quantitatively supported by comprehensive simulations with remarkable agreement. Our findings lay a theoretical foundation for designing nanofluidics-enabled cooling strategies and devices.

Topics & Concepts

NanofluidicsThermal conductivityNanoelectronicsChemical physicsMolecular dynamicsCarbon nanotubeMaterials scienceNanotechnologyThermalNanotubeHydrogen bondMass transportLiquid waterChemistryThermodynamicsEngineering physicsComputational chemistryMoleculePhysicsComposite materialOrganic chemistryNanopore and Nanochannel Transport StudiesThermal properties of materialsFuel Cells and Related Materials