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Journal Abstract Search

279 related items for PubMed ID: 22456273

  • 21. Unidirectional Fast Growth and Forced Jumping of Stretched Droplets on Nanostructured Microporous Surfaces.
    Aili A, Li H, Alhosani MH, Zhang T.
    ACS Appl Mater Interfaces; 2016 Aug 24; 8(33):21776-86. PubMed ID: 27486890
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  • 24. Rationally 3D-Textured Copper Surfaces for Laplace Pressure Imbalance-Induced Enhancement in Dropwise Condensation.
    Sharma CS, Stamatopoulos C, Suter R, von Rohr PR, Poulikakos D.
    ACS Appl Mater Interfaces; 2018 Aug 29; 10(34):29127-29135. PubMed ID: 30067013
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  • 25. Nanoparticles of varying hydrophobicity at the emulsion droplet-water interface: adsorption and coalescence stability.
    Simovic S, Prestidge CA.
    Langmuir; 2004 Sep 14; 20(19):8357-65. PubMed ID: 15350114
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  • 26. Evaporative properties and pinning strength of laser-ablated, hydrophilic sites on lotus-leaf-like, nanostructured surfaces.
    McLauchlin ML, Yang D, Aella P, Garcia AA, Picraux ST, Hayes MA.
    Langmuir; 2007 Apr 24; 23(9):4871-7. PubMed ID: 17381139
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  • 27. Dropwise Condensate Comb for Enhanced Heat Transfer.
    Tang Y, Yang X, Wang L, Li Y, Zhu D.
    ACS Appl Mater Interfaces; 2023 May 03; 15(17):21549-21561. PubMed ID: 37083343
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  • 28. From Initial Nucleation to Cassie-Baxter State of Condensed Droplets on Nanotextured Superhydrophobic Surfaces.
    Lv C, Zhang X, Niu F, He F, Hao P.
    Sci Rep; 2017 Feb 16; 7():42752. PubMed ID: 28202939
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  • 30. Nanoarray-Embedded Hierarchical Surfaces for Highly Durable Dropwise Condensation.
    Hu Y, Jiang K, Liew KM, Zhang LW.
    Research (Wash D C); 2022 Feb 16; 2022():9789657. PubMed ID: 36061819
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  • 31. Liquid-Infused Smooth Surface for Improved Condensation Heat Transfer.
    Tsuchiya H, Tenjimbayashi M, Moriya T, Yoshikawa R, Sasaki K, Togasawa R, Yamazaki T, Manabe K, Shiratori S.
    Langmuir; 2017 Sep 12; 33(36):8950-8960. PubMed ID: 28826213
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  • 32. Rationalization of the behavior of solid-liquid surface free energy of water in Cassie and Wenzel wetting states on rugged solid surfaces at the nanometer scale.
    Leroy F, Müller-Plathe F.
    Langmuir; 2011 Jan 18; 27(2):637-45. PubMed ID: 21142209
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  • 33. Evaporation-Crystallization Method to Promote Coalescence-Induced Jumping on Superhydrophobic Surfaces.
    Han T, Choi Y, Kwon JT, Kim MH, Jo H.
    Langmuir; 2020 Aug 25; 36(33):9843-9848. PubMed ID: 32787044
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  • 36. Predictive model for ice formation on superhydrophobic surfaces.
    Bahadur V, Mishchenko L, Hatton B, Taylor JA, Aizenberg J, Krupenkin T.
    Langmuir; 2011 Dec 06; 27(23):14143-50. PubMed ID: 21899285
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  • 37. Superhydrophobic nanostructured silicon surfaces with controllable broadband reflectance.
    Cho SJ, An T, Kim JY, Sung J, Lim G.
    Chem Commun (Camb); 2011 Jun 07; 47(21):6108-10. PubMed ID: 21523314
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  • 39. 3D Imaging of Water-Drop Condensation on Hydrophobic and Hydrophilic Lubricant-Impregnated Surfaces.
    Kajiya T, Schellenberger F, Papadopoulos P, Vollmer D, Butt HJ.
    Sci Rep; 2016 Apr 04; 6():23687. PubMed ID: 27040483
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  • 40. Design of ice-free nanostructured surfaces based on repulsion of impacting water droplets.
    Mishchenko L, Hatton B, Bahadur V, Taylor JA, Krupenkin T, Aizenberg J.
    ACS Nano; 2010 Dec 28; 4(12):7699-707. PubMed ID: 21062048
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