Enhanced pool-boiling heat transfer and critical heat flux on femtosecond laser processed stainless steel surfaces

Kruse, Corey; Anderson, Troy D.; Wilson, Chris; Zuhlke, Craig; Alexander, Dennis R.; Gogos, George; Ndao, Sidy

doi:10.1016/j.ijheatmasstransfer.2014.11.023

Cited by 215 publications

(55 citation statements)

References 33 publications

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“…Throughout the literature, only a few examples of secondary boiling effects can be found. 6,21,24,25 Secondary boiling effects can be seen on 10 lm silicon nanowire surfaces, stainless steel surfaces with 200 lm aluminum porous coatings, 21 35 lm tall stainless steel mound structures with a nanoporous layer, 24 and 400 lm tall copper microchannels with a porous coating. 25 An attempt to explain secondary boiling effects has been given by Chen et al 6 and Patil et al 25 In the work conducted by Chen et al, secondary boiling effects were seen on 10 lm tall silicon nanowires.…”

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confidence: 99%

“…Heat flux is measured via embedded thermocouples and surface temperature is calculated. A more in depth description of the FLSP technique and the pool boiling experimental setup is given by Kruse et al 24,26 Five unique surfaces are analyzed in this work, two Inconel, two stainless steel, and one copper. Their surface characteristics have been obtained using a Keyence Laser Confocal Microscope and are tabulated in Table I.…”

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Secondary pool boiling effects

Kruse

Tsubaki

Zuhlke

et al. 2016

Applied Physics Letters

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A pool boiling phenomenon referred to as secondary boiling effects is discussed. Based on the experimental trends, a mechanism is proposed that identifies the parameters that lead to this phenomenon. Secondary boiling effects refer to a distinct decrease in the wall superheat temperature near the critical heat flux due to a significant increase in the heat transfer coefficient. Recent pool boiling heat transfer experiments using femtosecond laser processed Inconel, stainless steel, and copper multiscale surfaces consistently displayed secondary boiling effects, which were found to be a result of both temperature drop along the microstructures and nucleation characteristic length scales. The temperature drop is a function of microstructure height and thermal conductivity. An increased microstructure height and a decreased thermal conductivity result in a significant temperature drop along the microstructures. This temperature drop becomes more pronounced at higher heat fluxes and along with the right nucleation characteristic length scales results in a change of the boiling dynamics. Nucleation spreads from the bottom of the microstructure valleys to the top of the microstructures, resulting in a decreased surface superheat with an increasing heat flux. This decrease in the wall superheat at higher heat fluxes is reflected by a “hook back” of the traditional boiling curve and is thus referred to as secondary boiling effects. In addition, a boiling hysteresis during increasing and decreasing heat flux develops due to the secondary boiling effects. This hysteresis further validates the existence of secondary boiling effects.

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confidence: 99%

Secondary pool boiling effects

Kruse

Tsubaki

Zuhlke

et al. 2016

Applied Physics Letters

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“…As an alternative explanation, when using the dual-pulse technique the second pulse may reheat the plasma from the first pulse, resulting in a hotter plasma than when using single-pulse FLSP (Zhao and Shin 2015). The hotter plasma may be needed to drive (Groeneveld et al 1995) None Nickel 8 (Beaurepaire et al 1996) Yes (Zuhlke et al 2013) Titanium 18.5 (Ahmmed et al 2015) Yes (Vorobyev and Guo 2007) 304 Stainless steel 14.4 (Winter et al 2016) Yes (Kruse et al 2015) the self-organization processes for the structures to form on silver.…”

Section: Discussionmentioning

confidence: 99%

“…Femtosecond laser surface processing (FLSP) is a developing technique for creating micro/nanoscale surfaces with a wide range of applications including improved heat transfer (Kruse et al 2013(Kruse et al , 2015(Kruse et al , 2016, medical implants (Vorobyev and Guo 2007), improving efficiency of electrolysis cells , and controlling material wetting properties (Zuhlke et al 2013). In most of these applications, the greatest enhancements result from a surface with a combination of micro and nanoscale surface features.…”

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confidence: 99%

Creation of micro/nano surface structures on silver using collinear double femtosecond laser pulses with different pulse separation

Roth

Zuhlke

Peng

et al. 2018

Multiscale and Multidiscip. Model. Exp. and Des.

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Self-organized mound-like micro/nanoscale structures are reported for the first time on silver using a dual-pulse femtosecond laser surface processing technique. The dual-pulse laser processing technique reported in this paper uses femtosecond laser pulse pairs with a controlled temporal delay between the leading and trailing pulses. Using dual pulses at higher fluence values, mound-like micro/nanostructures have been created on silver samples for the first time. Formation of the self-organized microstructures is shown to be dependent on the time delay between the leading and trailing pulses. Mound-like microstructures do not develop on silver for overlapped pulses or using single-pulse femtosecond laser surface processing for the parameter space studied. Subsurface microstructure characterization of a single mound-like surface structure is analyzed by crosssectional analysis using focused ion beam milling followed by scanning electron microscopy and energy dispersive X-ray spectroscopy.

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“…This reduction in solid-liquid contact area means that the heat flux required to generate the supporting vapour layer required for a Leidenfrost state has to be transferred through the reduced contact area between the liquid and the solid wires. This would mean that a higher temperature is needed for the required heat flux to generate a continuous vapour and so produce a Leidenfrost state [21][22][23][24]. Figure 2(b), degrades the fit, suggesting that this area is not a significant factor.…”

Section: Meshmentioning

confidence: 99%

Leidenfrost transition temperature for stainless steel meshes

Geraldi

McHale

et al. 2016

Materials Letters

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(2016) 'Leidenfrost transition temperature for stainless steel meshes. ', Materials letters., Further information on publisher's website: Use policyThe full-text may be used and/or reproduced, and given to third parties in any format or medium, without prior permission or charge, for personal research or study, educational, or not-for-prot purposes provided that:• a full bibliographic reference is made to the original source • a link is made to the metadata record in DRO • the full-text is not changed in any way The full-text must not be sold in any format or medium without the formal permission of the copyright holders.Please consult the full DRO policy for further details. AbstractOn surfaces well above 100°C water does not simply boil away. When there is a sufficient heat transfer between the solid and the liquid a continuous vapour layer instantaneous forms under a droplet of water and the drop sits on a cushion of vapour, highly mobile and insulated from the solid surface. This is known as the Leidenfrost effect and the temperature at which this occurs if known as the Leidenfrost transition temperature. In this report, an investigation of discontinuous surfaces, stainless steel meshes, have been tested to determine the effect of the woven material on the Leidenfrost phenomenon. . This allows suppression of the Leidenfrost effect as it can be increase to over 300°C from 185°C for a stainless steel surface. Graphical Abstract Introduction

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Enhanced pool-boiling heat transfer and critical heat flux on femtosecond laser processed stainless steel surfaces

Cited by 215 publications

References 33 publications

Secondary pool boiling effects

Secondary pool boiling effects

Creation of micro/nano surface structures on silver using collinear double femtosecond laser pulses with different pulse separation

Leidenfrost transition temperature for stainless steel meshes

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