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      KCI등재 SCIE SCOPUS

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

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      https://www.riss.kr/link?id=A106259555

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      다국어 초록 (Multilingual Abstract)

      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 nan...

      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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      참고문헌 (Reference)

      1 C. T. Nguyen, "Wetting of chemically heterogeneous striped surfaces : Molecular dynamics simulations" 8 : 065003-, 2018

      2 J. Muscatello, "Water under temperature gradients : Polarization effects and microscopic mechanisms of heat transfer" 13 : 19970-19978, 2011

      3 B. H. Kim, "Viscous heating in nanoscale shear driven liquid flows" 9 : 31-40, 2010

      4 T. Q. Vo, "Transport phenomena of water in molecular fluidic channels" 6 : 33881-, 2016

      5 B. Kim, "Thermal resistance at a liquid-solid interface dependent on the ratio of thermal oscillation frequencies" 554 : 77-81, 2012

      6 B. H. Kim, "Thermal interactions in nanoscale fluid flow : molecular dynamics simulations with solid-liquid interfaces" 5 : 551-559, 2008

      7 W. Evans, "Thermal conductivity of ordered molecular water" 126 : 154504-, 2007

      8 B. D. Todd, "Temperature profile for Poiseuille flow" 55 : 2800-2807, 1997

      9 Chinh Thanh Nguyen, "Stress and Surface Tension Analyses of Water on Graphene-Coated Copper Surfaces" 한국정밀공학회 17 (17): 503-510, 2016

      10 C. T. Nguyen, "Saltwater transport through pristine and positively charged graphene membranes" 149 : 024704-, 2018

      1 C. T. Nguyen, "Wetting of chemically heterogeneous striped surfaces : Molecular dynamics simulations" 8 : 065003-, 2018

      2 J. Muscatello, "Water under temperature gradients : Polarization effects and microscopic mechanisms of heat transfer" 13 : 19970-19978, 2011

      3 B. H. Kim, "Viscous heating in nanoscale shear driven liquid flows" 9 : 31-40, 2010

      4 T. Q. Vo, "Transport phenomena of water in molecular fluidic channels" 6 : 33881-, 2016

      5 B. Kim, "Thermal resistance at a liquid-solid interface dependent on the ratio of thermal oscillation frequencies" 554 : 77-81, 2012

      6 B. H. Kim, "Thermal interactions in nanoscale fluid flow : molecular dynamics simulations with solid-liquid interfaces" 5 : 551-559, 2008

      7 W. Evans, "Thermal conductivity of ordered molecular water" 126 : 154504-, 2007

      8 B. D. Todd, "Temperature profile for Poiseuille flow" 55 : 2800-2807, 1997

      9 Chinh Thanh Nguyen, "Stress and Surface Tension Analyses of Water on Graphene-Coated Copper Surfaces" 한국정밀공학회 17 (17): 503-510, 2016

      10 C. T. Nguyen, "Saltwater transport through pristine and positively charged graphene membranes" 149 : 024704-, 2018

      11 T. Q. Vo, "Physical origins of temperature continuity at an interface between a crystal and its melt" 148 : 034703-, 2018

      12 T. Q. Vo, "Near-surface viscosity effects on capillary rise of water in nanotubes" 92 : 053009-, 2015

      13 D. G. Cahill, "Nanoscale thermal transport" 93 : 793-818, 2003

      14 Truong Quoc Vo, "Nano-scale liquid film sheared between strong wetting surfaces: effects of interface region on the flow" 대한기계학회 29 (29): 1681-1688, 2015

      15 B. H. Kim, "Molecular dynamics simulations of thermal resistance at the liquid-solid interface" 129 : 174701-, 2008

      16 M. Barisik, "Molecular dynamics simulations of shear-driven gas flows in nano-channels" 11 : 611-622, 2011

      17 C. Y. Soong, "Molecular dynamics simulation of nanochannel flows with effects of wall lattice-fluid interactions" 76 : 2007

      18 M. R. Hasan, "Manipulating thermal resistance at the solid-fluid interface through monolayer deposition" 9 : 4948-4956, 2019

      19 S. Nakaoka, "Local viscosity change in the water near a solid-liquid interface and its extraction by means of molecular rotational diffusion-A molecular dynamics study" 591 : 306-311, 2014

      20 G. L. Pollack, "Kapitza resistance" 41 : 48-, 1969

      21 A. T. Pham, "Interfacial thermal resistance between the graphene-coated copper and liquid water" 97 : 422-431, 2016

      22 Truong Quoc Vo, "Interface Thermal Resistance between Liquid Water and Various Metallic Surfaces" 한국정밀공학회 16 (16): 1341-1346, 2015

      23 S. Plimpton, "Fast parallel algorithms for short-range molecular dynamics" 117 : 1-19, 1995

      24 B. Hess, "Determining the shear viscosity of model liquids from molecular dynamics simulations" 116 : 209-217, 2002

      25 J. Sun, "Dependence between velocity slip and temperature jump in shear flows" 138 : 2013

      26 M. Allen, "Computer Simulation of Liquids" Oxford Science 1990

      27 T. Q. Vo, "Atomic density effects on temperature characteristics and thermal transport at grain boundaries through a proper bin size selection" 144 : 194707-, 2016

      28 P. A. Thompson, "A general boundary condition for liquid flow at solid surfaces" 389 : 360-362, 1997

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      학술지 이력

      학술지 이력
      연월일 이력구분 이력상세 등재구분
      2023 평가예정 해외DB학술지평가 신청대상 (해외등재 학술지 평가)
      2020-01-01 평가 등재학술지 유지 (해외등재 학술지 평가) KCI등재
      2012-11-05 학술지명변경 한글명 : 대한기계학회 영문 논문집 -> Journal of Mechanical Science and Technology KCI등재
      2010-01-01 평가 등재학술지 유지 (등재유지) KCI등재
      2008-01-01 평가 등재학술지 유지 (등재유지) KCI등재
      2006-01-19 학술지명변경 한글명 : KSME International Journal -> 대한기계학회 영문 논문집
      외국어명 : KSME International Journal -> Journal of Mechanical Science and Technology      		 KCI등재
      2006-01-01 평가 등재학술지 유지 (등재유지) KCI등재
      2004-01-01 평가 등재학술지 유지 (등재유지) KCI등재
      2001-01-01 평가 등재학술지 선정 (등재후보2차) KCI등재
      1998-07-01 평가 등재후보학술지 선정 (신규평가) KCI등재후보
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      기준연도 WOS-KCI 통합IF(2년) KCIF(2년) KCIF(3년)
      2016 1.04 0.51 0.84
      KCIF(4년) KCIF(5년) 중심성지수(3년) 즉시성지수
      0.74 0.66 0.369 0.12
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