A point sink superposition method for predicting droplet interaction effects during vapor-diffusion-driven dropwise condensation in humid air

Castillo, Julian E.; Weibel, Justin A.

doi:10.1016/j.ijheatmasstransfer.2017.11.045

Cited by 23 publications

(12 citation statements)

References 27 publications

(50 reference statements)

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“…However, since most gas molecules exist in a high concentration near the central axis, several nanodroplets are generated and are in contact with one another. 62,63 As shown in a cryo-SEM image, their contact coalesces into large microdroplets near the center. 63,64 Consequently, the diameter of the droplets decreased as its position moved radially outward where droplets had rarely coalesced.…”

Section: Resultsmentioning

confidence: 99%

A laser-driven optical atomizer: photothermal generation and transport of zeptoliter-droplets along a carbon nanotube deposited hollow optical fiber

et al. 2022

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Section: Resultsmentioning

confidence: 99%

A laser-driven optical atomizer: photothermal generation and transport of zeptoliter-droplets along a carbon nanotube deposited hollow optical fiber

et al. 2022

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“…This has been done using the point sink superposition method (Figure 4c). [92,93] Based on the present literature, I believe that particularly three recurring themes are currently limiting the full utilization of spatial control. These are 1) their issues with robustness, 2) their fixed behavior, and 3) only spatial control of water is considered.…”

Section: Vapor Sinks and Depletion Zonesmentioning

confidence: 95%

Spatial Control of Condensation: The Past, the Present, and the Future

Mandsberg

2021

Adv Materials Inter

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reproducible outcomes are not guaranteed and experiments at this small scale are difficult to characterize. Transcending the randomness would have immense environmental, safety, and economic consequences.A critical element in understanding condensate behavior is the distinction between homo-and heterogenous nucleation. The former case describes a spontaneous nucleus formation in the gas phase, a process that is typically orders of magnitude less likely to occur than its heterogenous counterpart, where nucleation happens at a solid-gas or liquid-gas interface. [8] Therefore, heterogeneities in the system can serve as trigger points for nucleation and deliberate positioning of interfaces can shift the condensation toward specific and predetermined locations. Introducing such nucleation catalysts to alter the random nature is the focus of this review; more popularly phrased, I answer the question: what are the options to achieve spatial control of condensation? Within each category, I discuss its strengths and limitations, with consideration to the degree of control possible and practical considerations such as scalability.

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“…The point sink superposition method solves for the diffusion of vapor within the air domain surrounding the droplets during dropwise condensation. Our previous work [15] provides a complete description of the method which is briefly summarized here. The model assumes: (i) droplets can be treated as point sinks located at the droplet centers, (ii) the condensation process can be treated as quasi-steady state, (iii) there is negligible thermal resistance across the droplets (i.e., the temperature at the surface of the droplet is equal to the temperature of the substrate), (iv) the contact angle of the droplets is independent of droplet size, and (v) changes in vapor concentration at the surface of the droplets due to curvature are negligible.…”

Section: The Point Sink Superposition Methods (Pssm)mentioning

confidence: 99%

“…At later times, droplets that have polygons with larger areas do not necessarily grow faster. We have previously shown that the condensation rate of pairs of droplets predicted by the PSSM is sensitive to the ratio of between the droplet sizes [15]. Large droplets can limit the vapor diffusion to small droplets in their surroundings For example, droplet h in Figure 9 (b) has a larger Voronoi polygon area than its neighbor droplet l , but grows at a smaller rate, because droplet l has a larger size and it is surrounded by smaller neighbors than droplet h .…”

Section: Effects Of Droplet Size and Spatial Distribution On The Condmentioning

confidence: 97%

“…To account for the complete set of interactions between all droplets on the substrate, communicated through the vapor concentration field, we recently developed a point source superposition method to describe droplet growth during dropwise condensation [15]. By assuming that each droplet can be treated as point sink for vapor, this method solves for the condensation rate of each droplet within a system of many droplets by superposing a modified version of Popov's solution [16] for the condensation of individual droplets; the point sink superposition method was demonstrated to be in reasonable agreement with complete numerical solutions of the vapor diffusion equation.…”

Section: Introductionmentioning

confidence: 99%

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Predicting the growth of many droplets during vapor-diffusion-driven dropwise condensation experiments using the point sink superposition method

Castillo

Weibel

2019

International Journal of Heat and Mass Transfer

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Water vapor present in humid air will condense in the form of many small droplets on a cooled substrate. After nucleation, the diffusion of vapor from the environment to the droplets dominates their growth by condensation, and therefore, all droplets must compete for the vapor available in the surroundings. Models that assume droplets grow in isolation or as an equivalent film poorly capture their interaction during vapor-diffusion-driven condensation and do not correspond with experimental condensation rates. By treating the droplets as point sinks, the interaction between all droplets in a system can be captured by superposing the vapor distributions of each droplet. This paper presents direct comparisons of condensation rates measured in experiments and predicted with a point sink superposition method. The results indicate that it is critical to consider a large number of interacting droplets to accurately predict the condensation behavior. Even though the intensity of the interaction between droplets decreases sharply with their separation distance, droplets located relatively far away from a given droplet must be considered to accurately predict its condensation rate, due to the large aggregate effect of all such far away droplets. By considering an appropriate number of interacting droplets in a system, the point sink superposition method is able to predict experimental condensation rates to within 5%. Diffusion-based models that neglect the interactions of droplets located far away, or approximate droplet growth as an equivalent film, are shown to overpredict condensation rates. exp experiment film film-like growth model iso isolated from all neighboring droplets l liquid PSSM point sink superposition method s at the surface of the drop sub at the substrate sys in the system of droplets  far field

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A point sink superposition method for predicting droplet interaction effects during vapor-diffusion-driven dropwise condensation in humid air

Cited by 23 publications

References 27 publications

A laser-driven optical atomizer: photothermal generation and transport of zeptoliter-droplets along a carbon nanotube deposited hollow optical fiber

A laser-driven optical atomizer: photothermal generation and transport of zeptoliter-droplets along a carbon nanotube deposited hollow optical fiber

Spatial Control of Condensation: The Past, the Present, and the Future

Predicting the growth of many droplets during vapor-diffusion-driven dropwise condensation experiments using the point sink superposition method

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