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Your search keyword '"Cropek, Donald M."' showing total 7 results
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7 results on '"Cropek, Donald M."'

4. Particulate–Droplet Coalescence and Self-Transport on Superhydrophobic Surfaces

Author

Yan, Xiao, primary, Ji, Bingqiang, additional, Feng, Lezhou, additional, Wang, Xiong, additional, Yang, Daolong, additional, Rabbi, Kazi Fazle, additional, Peng, Qi, additional, Hoque, Muhammad Jahidul, additional, Jin, Puhang, additional, Bello, Elizabeth, additional, Sett, Soumyadip, additional, Alleyne, Marianne, additional, Cropek, Donald M., additional, and Miljkovic, Nenad, additional

Published
2022
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5. Particulate-Droplet Coalescence and Self-Transport on Superhydrophobic Surfaces

Author

Yan, Xiao, Ji, Bingqiang, Feng, Lezhou, Wang, Xiong, Yang, Daolong, Rabbi, Kazi Fazle, Peng, Qi, Hoque, Muhammad Jahidul, Jin, Puhang, Bello, Elizabeth, Sett, Soumyadip, Alleyne, Marianne, Cropek, Donald M., Miljkovic, Nenad, Yan, Xiao, Ji, Bingqiang, Feng, Lezhou, Wang, Xiong, Yang, Daolong, Rabbi, Kazi Fazle, Peng, Qi, Hoque, Muhammad Jahidul, Jin, Puhang, Bello, Elizabeth, Sett, Soumyadip, Alleyne, Marianne, Cropek, Donald M., and Miljkovic, Nenad

Abstract

Particulate transport from surfaces governs a variety of phenomena including fungal spore dispersal, bioaerosol transmission, and self-cleaning. Here, we report a previously unidentified mechanism governing passive particulate removal from superhydrophobic surfaces, where a particle coalescing with a water droplet (similar to 10 to similar to 100 mu m) spontaneously launches. Compared to previously discovered coalescence-induced binary droplet jumping, the reported mechanism represents a more general capillary-inertial dominated transport mode coupled with particle/droplet properties and is typically mediated by rotation in addition to translation. Through wetting and momentum analyses, we show that transport physics depends on particle/droplet density, size, and wettability. The observed mechanism presents a simple and passive pathway to achieve self-cleaning on both artificial as well as biological materials as confirmed here with experiments conducted on butterfly wings, cicada wings, and clover leaves. Our findings provide insights into particle-droplet interaction and spontaneous particulate transport, which may facilitate the development of functional surfaces for medical, optical, thermal, and energy applications.

Published
2022

6. A 3D Interconnected Microchannel Network Formed in Gelatin by Sacrificial Shellac Microfibers

Author

Koch Institute for Integrative Cancer Research at MIT, Bellan, Leon M., Pearsall, Matthew, Cropek, Donald M., Langer, Robert S, Koch Institute for Integrative Cancer Research at MIT, Bellan, Leon M., Pearsall, Matthew, Cropek, Donald M., and Langer, Robert S

Abstract

3D microfluidic networks are fabricated in a gelatin hydrogel using sacrificial melt-spun microfibers made from a material with pH-dependent solubility. The fibers, after being embedded within the gel, can be removed by changing the gel pH to induce dissolution. This process is performed in an entirely aqueous environment, avoiding extreme temperatures, low pressures, and toxic organic solvents. Copyright © 2012 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.

Published
2022

7. Exploring the Role of Habitat on the Wettability of Cicada Wings

Author

Oh, Junho, Dana, Catherine E., Hong, Sungmin, Román, Jessica K., Jo, Kyoo Dong, Hong, Je Won, Nguyen, Jonah, Cropek, Donald M., Alleyne, Marianne, and Miljkovic, Nenad

Abstract

Evolutionary pressure has pushed many extant species to develop micro/nanostructures that can significantly affect wettability and enable functionalities such as droplet jumping, self-cleaning, antifogging, antimicrobial, and antireflectivity. In particular, significant effort is underway to understand the insect wing surface structure to establish rational design tools for the development of novel engineered materials. Most studies, however, have focused on superhydrophobic wings obtained from a single insect species, in particular, the Psaltoda claripenniscicada. Here, we investigate the relationship between the spatially dependent wing wettability, topology, and droplet jumping behavior of multiple cicada species and their habitat, lifecycle, and interspecies relatedness. We focus on cicada wings of four different species: Neotibicen pruinosus, N. tibicen, Megatibicen dorsatus, and Magicicada septendecimand take a comparative approach. Using spatially resolved microgoniometry, scanning electron microscopy, atomic force microscopy, and high speed optical microscopy, we show that within cicada species, the wettability of wings is spatially homogeneous across wing cells. All four species were shown to have truncated conical pillars with widely varying length scales ranging from 50 to 400 nm in height. Comparison of the wettability revealed three cicada species with wings that are superhydrophobic (>150°) with low contact angle hysteresis (<5°), resulting in stable droplet jumping behavior. The fourth, more distantly related species (Ma. septendecim) showed only moderate hydrophobic behavior, eliminating some of the beneficial surface functional aspects for this cicada. Correlation between cicada habitat and wing wettability yielded little connection as wetter, swampy environments do not necessarily equate to higher measured wing hydrophobicity. The results, however, do point to species relatedness and reproductive strategy as a closer proxy for predicting wettability and surface structure and resultant enhanced wing surface functionality. This work not only elucidates the differences between inter- and intraspecies cicada wing topology, wettability, and water shedding behavior but also enables the development of rational design tools for the manufacture of artificial surfaces for energy and water applications.

Published
2024
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