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Electron cooling in graphene enhanced by plasmon–hydron resonance

Xiaoqing Yu, Alessandro Principi, Klaas‐Jan Tielrooij, Mischa Bonn, Nikita Kavokine

2023Nature Nanotechnology45 citationsDOIOpen Access PDF

Abstract

Evidence is accumulating for the crucial role of a solid's free electrons in the dynamics of solid-liquid interfaces. Liquids induce electronic polarization and drive electric currents as they flow; electronic excitations, in turn, participate in hydrodynamic friction. Yet, the underlying solid-liquid interactions have been lacking a direct experimental probe. Here we study the energy transfer across liquid-graphene interfaces using ultrafast spectroscopy. The graphene electrons are heated up quasi-instantaneously by a visible excitation pulse, and the time evolution of the electronic temperature is then monitored with a terahertz pulse. We observe that water accelerates the cooling of the graphene electrons, whereas other polar liquids leave the cooling dynamics largely unaffected. A quantum theory of solid-liquid heat transfer accounts for the water-specific cooling enhancement through a resonance between the graphene surface plasmon mode and the so-called hydrons-water charge fluctuations-particularly the water libration modes, which allows for efficient energy transfer. Our results provide direct experimental evidence of a solid-liquid interaction mediated by collective modes and support the theoretically proposed mechanism for quantum friction. They further reveal a particularly large thermal boundary conductance for the water-graphene interface and suggest strategies for enhancing the thermal conductivity in graphene-based nanostructures.

Topics & Concepts

GrapheneMaterials scienceElectronChemical physicsPlasmonCondensed matter physicsNanotechnologyOptoelectronicsChemistryPhysicsQuantum mechanicsThermal Radiation and Cooling TechnologiesAdvanced Thermodynamics and Statistical MechanicsQuantum Electrodynamics and Casimir Effect
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