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Roach P, Shirtcliffe NJ, Newton MI (2008) Progess in superhydrophobic surface development. Plötze M, Niemz P (2011) Porosity and pore size distribution of different wood types as determined by mercury intrusion porosimetry. Parmak EDS (2016) Fabrication of microstructured polymers by a simple biotemplate embossing method and their characterization.
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Parker AR, Lawrence CR (2001) Water capture by a desert beetle. Effects of topography length scales on wettability. Öner D, McCarthy TJ (2000) Ultrahydrophobic surfaces. Nosonovsky M, Bhushan B (2008) Lotus-effect and water-repellent surfaces in nature multiscale dissipative mechanisms and hierarchical surfaces: friction, superhydrophobicity, and biomimetics, pp 181–197 Miyauchi Y, Ding B, Shiratori S (2006) Fabrication of a silver-ragwort-leaf-like super-hydrophobic micro/nanoporous fibrous mat surface by electrospinning. Mele E, Girardo S, Pisignano D (2012) Strelitzia reginae leaf as a natural template for anisotropic wetting and superhydrophobicity. Lee K, Lyu S, Lee S, Kim YS, Hwang W (2010) Characteristics and self-cleaning effect of the transparent super-hydrophobic film having nanofibers array structures. Kreder MJ, Alvarenga J, Kim P, Aizenberg J (2016) Design of anti-icing surfaces: smooth, textured or slippery? Nat Rev Mater 1:15003 Kitin P, Sano Y, Funada R (2001) Analysis of cambium and differentiating vessel elements in Kalopanax pictus using resin cast replicas. Kiaei M, Samariha A (2011) Fiber dimensions, physical and mechanical properties of five important hardwood plants. Ju J, Bai H, Zheng Y, Zhao T, Fang R, Jiang L (2012) A multi-structural and multi-functional integrated fog collection system in cactus. Hao B, Lin W, Jie J, Ruize S, Yongmei Z, Lei J (2014) Efficient water collection on integrative bioinspired surfaces with star-shaped wettability patterns. Guo H et al (2017) Bio-inspired superhydrophobic and omniphobic wood surfaces advanced materials. Gorb SN (2009) Functional surfaces in biology: little structures with big effects, vol 1. Ghosh A, Ganguly R, Schutzius TM, Megaridis CM (2014) Wettability patterning for high-rate, pumpless fluid transport on open, non-planar microfluidic platforms. Gao X, Jiang L (2004) Biophysics: water-repellent legs of water striders. Mater Today 18:273–285įlowers G, Switzer ST (1978) Background material properties of selected silicone potting compounds and raw materials for their substitutes. Nanotechnology 17:1359ĭarmanin T, Guittard F (2015) Superhydrophobic and superoleophobic properties in nature. Trans Faraday Soc 40:546–551Ĭheng YT, Rodak D, Wong C, Hayden C (2006) Effects of micro-and nano-structures on the self-cleaning behaviour of lotus leaves.
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Ĭassie A, Baxter S (1944) Wettability of porous surfaces. Philos Trans R Soc A Math Phys Eng Sci 370:2381–2417. īixler GD, Bhushan B (2012) Biofouling: lessons from nature. Philos Trans R Soc A Math Phys Eng Sci 367:1631–1672.
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Los Alamos National Laboratory (LANL), Los Alamosīhushan B, Jung YC, Koch K (2009) Micro-, nano- and hierarchical structures for superhydrophobicity, self-cleaning and low adhesion. īello M, Welch C, Goodwin L, Keller J (2014) Sylgard ® mixing study. īaquedano E, Martinez RV, Llorens JM, Postigo PA (2017) Fabrication of silicon nanobelts and nanopillars by soft lithography for hydrophobic and hydrophilic photonic surfaces. Fagus sylvatica wood cross sections are therefore simple, scalable, and inexpensive templates to manufacture structured surfaces, with the possibility to adjust wettability according to application needs.Īutumn K, Hansen W (2006) Ultrahydrophobicity indicates a non-adhesive default state in gecko setae. The wettability of the templated surfaces as a function of the different pillars heights was studied, and the optimal pillar aspect ratio was identified to enhance the hydrophobicity of the PDMS structured surfaces (reaching a water contact angle of 156°). By adjusting the PDMS pre-curing time, the extent of PDMS penetration could be controlled inside the wood capillaries, inducing the formation of pillars with various aspect ratios. The resulting PDMS-positive replicas show an arrangement of pillars, contributing to surface structuration. Microtomed transverse sections of beech wood were directly used as templates, and an accurate replication of the anatomical wood features (vessels and fibers) was obtained. Inspired by the hierarchical and porous wood microstructure, polydimethylsiloxane (PDMS)-positive replicas of beech ( Fagus sylvatica) cross sections, with superhydrophobic properties, were fabricated.