Craig Zuhlke scite author profile

"Formation of multiscale surface structures on nickel via above surface growth and below surface growth mechanisms using femtosecond laser pulses" (2013 Abstract:The formation of self-organized micro-and nano-structured surfaces on nickel via both above surface growth (ASG) and below surface growth (BSG) mechanisms using femtosecond laser pulse illumination is reported. Detailed stepped growth experiments demonstrate that conical mound-shaped surface structure development is characterized by a balance of growth mechanisms including scattering from surface structures and geometric effects causing preferential ablation of the valleys, flow of the surface melt, and redeposition of ablated material; all of which are influenced by the laser fluence and the number of laser shots on the sample. BSG-mound formation is dominated by scattering, while ASG-mound formation is dominated by material flow and redeposition. This is the first demonstration to our knowledge of the use of femtosecond laser pulses to fabricate metallic surface structures that rise above the original surface. These results are useful in understanding the details of multi-pulse femtosecond laser interaction with metals.

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Extraordinary Shifts of the Leidenfrost Temperature from Multiscale Micro/Nanostructured Surfaces

Kruse

et al. 2013

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In the present work, the effects of surface chemistry and micro/nanostructuring on the Leidenfrost temperature are experimentally investigated. The functional surfaces were fabricated on a 304 stainless steel surface via femtosecond laser surface processing (FLSP). The droplet lifetime experimental method was employed to determine the Leidenfrost temperature for both machine-polished and textured surfaces. A precision dropper was used to control the droplet size to 4.2 μL and surface temperatures were measured by means of an embedded thermocouple. Extraordinary shifts in the Leidenfrost temperatures, as high as 175 °C relative to the polished surface, were observed with the laser-processed surfaces. These extraordinary shifts were attributed to nanoporosity, reduction in contact angle, intermittent liquid/solid contacts, and capillary wicking actions resulting from the presence of self-assembled nanoparticles formed on the surfaces. In addition to the shift in the Leidenfrost temperature, significant enhancement of the heat transfer in the film boiling regime was also observed for the laser-processed surfaces; water droplet evaporation times were reduced by up to 33% for a surface temperature of 500 °C.

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

Kruse

Anderson

Wilson

et al. 2015

International Journal of Heat and Mass Transfer

214

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In this paper, we present an experimental investigation of pool boiling heat transfer on multiscale (micro/nano) functionalized metallic surfaces. Heat transfer enhancement in metallic surfaces is very important for large scale high heat flux applications like in the nuclear power industry. The multiscale structures were fabricated via a femtosecond laser surface process (FLSP) technique, which forms self-organized mound-like microstructures covered by layers of nanoparticles. Using a pool boiling experimental setup with deionized water as the working fluid, both the heat transfer coefficients and critical heat flux were investigated. A polished reference sample was found to have a critical heat flux of 91 W/cm 2 at 40 °C of superheat and a maximum heat transfer coefficient of 23,000 W/m 2 K. The processed samples were found to have a maximum critical heat flux of 142 W/cm 2 at 29 °C and a maximum heat transfer coefficient of 67,400 W/m 2 K. It was found that the enhancement of the critical heat flux was directly related to the wetting and wicking ability of the surface which acts to replenish the evaporating liquid and delay critical heat flux. The heat transfer coefficients were also found to increase when the surface area ratio was increased as well as the microstructure peak-to-valley height. Enhanced nucleate boiling is the main heat transfer mechanism, and is attributed to an increase in surface area and nucleation site density.

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Fundamentals of layered nanoparticle covered pyramidal structures formed on nickel during femtosecond laser surface interactions

Zuhlke

Anderson

Alexander

2013

Applied Surface Science

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Comparison of the structural and chemical composition of two unique micro/nanostructures produced by femtosecond laser interactions on nickel

Zuhlke

Anderson

Alexander

2013

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The structural and chemical composition of two unique microstructures formed on nickel, with nanoscale features, produced using femtosecond laser surface processing (FLSP) techniques is reported in this paper. These two surface morphologies, termed mounds and nanoparticle-covered pyramids, are part of a larger class of self-organized micro/nanostructured surfaces formed using FLSP. Cross-sections of the structures produced using focused ion beam milling techniques were analyzed with a transmission electron microscope. Both morphologies have a solid core with a layer of nanoparticles on the surface. Energy dispersive X-ray spectroscopy by scanning transmission electron microscopy studies reveal that the nanoparticles are a nickel oxide, while the core material is pure nickel.

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Craig Zuhlke

Formation of multiscale surface structures on nickel via above surface growth and below surface growth mechanisms using femtosecond laser pulses

Extraordinary Shifts of the Leidenfrost Temperature from Multiscale Micro/Nanostructured Surfaces

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

Fundamentals of layered nanoparticle covered pyramidal structures formed on nickel during femtosecond laser surface interactions

Comparison of the structural and chemical composition of two unique micro/nanostructures produced by femtosecond laser interactions on nickel

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