Atomic density effects on temperature characteristics and thermal transport at grain boundaries through a proper bin size selection

Vo, Truong Quoc; Barışık, Murat; Kim, BoHung

doi:10.1063/1.4949763

Cited by 20 publications

(15 citation statements)

References 52 publications

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“…In other words, the momentum transfer at the solid-liquid interface is independent of VDOS; the wall-fluid binding energy and adsorbed liquid layer are the crucial factors. This finding differ highly from the case of solid−solid interface, where the overlap between the VDOS regulates the heat transfer 47 . A similar observation has been reported 48 .…”

Section: Resultscontrasting

confidence: 75%

Transport Phenomena of Water in Molecular Fluidic Channels

Kim

2016

Sci Rep

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In molecular-level fluidic transport, where the discrete characteristics of a molecular system are not negligible (in contrast to a continuum description), the response of the molecular water system might still be similar to the continuum description if the time and ensemble averages satisfy the ergodic hypothesis and the scale of the average is enough to recover the classical thermodynamic properties. However, even in such cases, the continuum description breaks down on the material interfaces. In short, molecular-level liquid flows exhibit substantially different physics from classical fluid transport theories because of (i) the interface/surface force field, (ii) thermal/velocity slip, (iii) the discreteness of fluid molecules at the interface and (iv) local viscosity. Therefore, in this study, we present the result of our investigations using molecular dynamics (MD) simulations with continuum-based energy equations and check the validity and limitations of the continuum hypothesis. Our study shows that when the continuum description is subjected to the proper treatment of the interface effects via modified boundary conditions, the so-called continuum-based modified-analytical solutions, they can adequately predict nanoscale fluid transport phenomena. The findings in this work have broad effects in overcoming current limitations in modeling/predicting the fluid behaviors of molecular fluidic devices.

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Section: Resultscontrasting

confidence: 75%

Transport Phenomena of Water in Molecular Fluidic Channels

Kim

2016

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“…1(c). The method has been widely used [7][8][9][10][11][12]. The shear-driven and force-driven flows are enabled by setting the wall a velocity of 50 nm/ns and by setting gravity of 49 m/s 2 .…”

Section: Simulation Model and Theoretical Backgroundmentioning

confidence: 99%

Viscous heating and temperature profiles of liquid water flows in copper nanochannel

Dinh

Kim

2019

J Mech Sci Technol

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Understanding nanoscale fluidic transport becomes increasingly important due to the rapid development of nanotechnology and nanofabrication. By using molecular dynamics (MD) simulations, we investigated the viscous heating of water flows in copper nanochannels. The two scenarios that were studied are Couette flows and Poiseuille flows. We observed the scale effects on the distribution of fluid density, streaming velocity, fluid viscosity, and temperature across the channel. The results revealed the significant effects of surface forces on causing a large deviation between simulation results and classical hypothesis. We found that the energy equation coupled with the thermal-slip boundary conditions still fails to predict the temperature distributions. Hereby, further scale effects are taken into account, which leads to better predictions. The model that we developed in this study shows the relative deviation to the simulation data within 5 %, which is small compared to the conventional continuum approach (i.e., up to 51 %).

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“…Experiments where the effective heat conductivity of graded materials is measured through time domain thermo-reflectance, have been addressed with Equations (4)-(6) [23,24]. The thermal resistance in solid-solid and solid-water interfaces has also been studied from the microscopic point of view with nonequilibrium molecular dynamics techniques [25,26].…”

Section: Initial and Boundary Conditionsmentioning

confidence: 99%

Controlling and Optimizing Entropy Production in Transient Heat Transfer in Graded Materials

Pérez-Barrera

Figueroa

Vázquez

2019

Entropy

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This paper presents a numerical analysis of the transient heat transfer problem arising when a functionally graded material is subjected to a fixed temperature difference. Varying the gradation of the system, the thermal performance of the material is assessed both in time-dependent and steady-state conditions by means of temperature profiles and entropy production. One of the main contributions of this paper is the analysis of the system in the transient, from which it is found that the entropy production has a non-monotonic behaviour since maximum and minimum values of this physical quantity could be identified by varying the grading profile of the material. The latter allows to propose an optimization criterion for functionally graded materials which consists of the identification of spatial regions where temperature gradients are large and find thermal conductivity profiles that attenuate those gradients, thus reducing the thermal stresses present inside the material.

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Atomic density effects on temperature characteristics and thermal transport at grain boundaries through a proper bin size selection

Cited by 20 publications

References 52 publications

Transport Phenomena of Water in Molecular Fluidic Channels

Transport Phenomena of Water in Molecular Fluidic Channels

Viscous heating and temperature profiles of liquid water flows in copper nanochannel

Controlling and Optimizing Entropy Production in Transient Heat Transfer in Graded Materials

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