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Paper detail

Molecular Dynamics Simulation of Bubble Nucleation in Hydrophilic Nanochannels by Surface Heating

Bubble nucleation in liquid confined in nanochannel is studied using molecular dynamics simulations and compared against nucleation in the liquid over smooth (i.e. without confinement). Nucleation is achieved by heating part of a surface to high temperatures using a surface-to-liquid heating algorithm implemented in LAMMPS. The surface hydrophilicity of nanochannels is increased to understand its effect on nucleation behavior. Liquid structuring is found to play a significant role in altering thermodynamic properties of density and pressure in the nanochannels, which in turn changes the enthalpy of vaporization. Increased surface hydrophilicity in nanochannels results in the delay of bubble formation as more energy is required for nucleation. Thus, bubble nucleation in hydrophilic nanochannels can dissipate higher heat fluxes and can potentially be used towards the thermal management of hot spots in power electronics.

preprint2022arXivOpen access
Manish GuptaShalabh C. Maroo
cond-mat.mes-hallphysics.flu-dyn
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Manish GuptaShalabh C. Maroo

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