Microscale Temperature Measurements Near the Contact Line of an Evaporating Thin Film in a V-Groove

Migliaccio, Christopher P.; Dhavaleswarapu, Hemanth K.; Garimella, Suresh V.

doi:10.1115/interpack2009-89134

Cited by 4 publications

(8 citation statements)

References 12 publications

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“…We have previously shown that a 50 μm region near the contact line of an evaporating meniscus contributes to as much as 50−70% of the total heat transfer from the meniscus depending on the heat flux and geometrical details. , These results were based on thermal analysis carried out on the basis of microscale infrared temperature measurements obtained in the region of the contact line. The infrared transparency of an 80 μm thick heptane film was exploited in these measurements.…”

Section: Resultsmentioning

confidence: 99%

“…A model developed by Wang et al showed that 8% of the heat transfer takes place from the thin-film region (0.16 μm long), but as much as 60% of the overall heat transfer takes place from a 5 μm long region. While all the above studies were conducted under saturated vapor conditions, more recently we have shown , that, in systems that are open to air, a 50 μm long region near the contact line contributes to nearly 50−70% of the heat transfer from an evaporating meniscus. It is to be noted that none of the above studies had access to local velocity measurements to quantify the evaporative mass loss in the thin-film region.…”

Section: Introductionmentioning

confidence: 99%

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Experimental Investigation of Evaporation from Low-Contact-Angle Sessile Droplets

et al. 2009

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Evaporating sessile drops remain pinned at the contact line during much of the evaporation process, and leave a ring of residue on the surface upon dryout. The intensive mass loss near the contact line causes solute particles to flow to the edge of the droplet and deposit at the contact line. The high vapor diffusion gradient and the low thermal resistance of the film near the contact line are responsible for very efficient mass transfer in this region. Although heat and mass transfer at the contact line have been extensively studied, well-characterized experiments remain scarce. The local mass transport in a 100-400 microm region near the contact line of a water droplet of radius 1810 microm on a glass substrate is experimentally quantified in the present work. Microparticle image velocimetry measurements of the three-dimensional flow field near the contact line are conducted to map the velocity field. Combined with high-resolution transient liquid profile shapes, the measured velocity field yields transient local evaporative mass fluxes near the contact line. The spatial and temporal distribution of the local evaporative flux is also documented. The temperature distribution in the droplet near the contact line is deduced from the local evaporative fluxes and interface mass transport theory.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Experimental Investigation of Evaporation from Low-Contact-Angle Sessile Droplets

et al. 2009

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“…Numerical simulations have compared the heat transfer performance of different microstructures for thin film evaporation [16]. Meanwhile, various experimental approaches have been used to study the relation between meniscus shape and heat transfer behavior, such as infrared [17], and interference imaging [18]. However, these previous experimental investigations were generally steady state or slowly varying measurements where a constant heat flux was applied and a steady-state temperature was measured.…”

Section: Introductionmentioning

confidence: 99%

Pulsed evaporative transient thermometry for temporally-resolved thermal measurements

Xiao

Wang

2013

International Journal of Heat and Mass Transfer

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“…Plenty of researches have been devoted in various areas including heat transfer (Ward and Duan 2004;Wang et al 2005;Suman 2008; Ranjan et al 2009), material (Nguyen andStebe 2002;Truskett and Stebe 2003;Uchiyama et al 2010), etc. In recent years with the development of the micro-fabrication techniques, Marangoni convections in micro channels and their potential applications in microfluidic controls and electronic cooling have been more and more attractive.…”

Section: Introductionmentioning

confidence: 99%

“…Ranjan et al (2009) numerically accounted the importance of the Marangoni effect in micro-scale heat transfer enhancement. Migliaccio et al (2009) and Wang et al (2010) discussed the Marangoni convections in V-groove channels for electronic cooling. The Marangoni convection was found playing important roles in determining the temperature distribution and the flow patterns.…”

Section: Introductionmentioning

confidence: 99%

Instability of Marangoni toroidal convection in a microchannel and its relevance with the flowing direction

Zhang

Wang

2011

Microfluid Nanofluid

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The instability of the Marangoni toroidal flows in microchannels is of interest in various areas such as microfluidics and heat transfer. Using pure liquid as working fluid in this study, the phenomena of Marangoni symmetry-to-asymmetry transition which does not arise from the buoyancy was observed. The experiments used a vertical cylindrical channel and the meniscus was formed at the bottom outlet to minimize the buoyant influences. Two microscopes were used to have top view and side view of the meniscus simultaneously. The Marangoni flow field on the meniscus was obtained by means of tracing particles. It was observed that the Marangoni flow on a concave meniscus was always nearly symmetrical, while that on a convex meniscus was out of symmetry with only one single vortex occupying the whole channel. The experimental results were highly consistent to the simulation results of authors' previous 3D numerical model (Pan and Wang in Microfluid Nanofluid 9:657, 2010). Theoretical analysis together with newly developed numerical models is employed to dig into the mechanisms. The inward (from the meniscus edge to the center) Marangoni flow is found not as stable as the outward one. Based on the heat transfer analysis, a concave meniscus always has a colder edge thus the flow is outward and stable; while a convex enough meniscus could have an inward flow thus not stable and tends to lose the symmetry. The amplification mechanism of the inward Marangoni flow is comprehensively explained. Two conditions are required for the inward flow to lose the symmetry, i.e., the bulk liquid must be warmer than the meniscus, and the Marangoni number must be above a certain small value.

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Microscale Temperature Measurements Near the Contact Line of an Evaporating Thin Film in a V-Groove

Cited by 4 publications

References 12 publications

Experimental Investigation of Evaporation from Low-Contact-Angle Sessile Droplets

Experimental Investigation of Evaporation from Low-Contact-Angle Sessile Droplets

Pulsed evaporative transient thermometry for temporally-resolved thermal measurements

Instability of Marangoni toroidal convection in a microchannel and its relevance with the flowing direction

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