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Review Article

Fluid Velocity Slip and Temperature Jump at a Solid Surface

[+] Author and Article Information
Jian-Jun Shu

School of Mechanical and
Aerospace Engineering,
Nanyang Technological University,
50 Nanyang Avenue,
Singapore 639798
e-mail: mjjshu@ntu.edu.sg

Ji Bin Melvin Teo, Weng Kong Chan

School of Mechanical and
Aerospace Engineering,
Nanyang Technological University,
50 Nanyang Avenue,
Singapore 639798

1Corresponding author.

Manuscript received October 5, 2016; final manuscript received March 6, 2017; published online March 20, 2017. Assoc. Editor: Herman J. H. Clercx.

Appl. Mech. Rev 69(2), 020801 (Mar 20, 2017) (13 pages) Paper No: AMR-16-1081; doi: 10.1115/1.4036191 History: Received October 05, 2016; Revised March 06, 2017

A comprehensive review of current analytical models, experimental techniques, and influencing factors is carried out to highlight the current challenges in this area. The study of fluid–solid boundary conditions has been ongoing for more than a century, starting from gas–solid interfaces and progressing to that of the more complex liquid–solid case. Breakthroughs have been made on the theoretical and experimental fronts but the mechanism behind the phenomena remains a puzzle. This paper provides a review of the theoretical models, and numerical and experimental investigations that have been carried out till date. Probable mechanisms and factors that affect the interfacial discontinuity are also documented.

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Figures

Grahic Jump Location
Fig. 1

Jump-type boundary conditions: (left) slip boundary condition—us: slip velocity, b: slip length. (Right) temperature jump boundary condition—ΔT: temperature jump, Tw: wall temperature, Tf: surface fluid temperature, and bT: temperature jump length.

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