Jumping-droplet-enhanced condensation on scalable superhydrophobic nanostructured surfaces.
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Evelyn N Wang | Jean Sack | Ryan Enright | Nenad Miljkovic | Youngsuk Nam | E. Wang | N. Miljkovic | R. Enright | Y. Nam | Ken Lopez | Nicholas Dou | K. Lopez | Nicholas G Dou | J. Sack
[1] Kripa K. Varanasi,et al. Spatial control in the heterogeneous nucleation of water , 2009 .
[2] E. Wang,et al. Growth Dynamics During Dropwise Condensation on Nanostructured Superhydrophobic Surfaces , 2012 .
[3] K. Kim,et al. Dropwise Condensation Modeling Suitable for Superhydrophobic Surfaces , 2011 .
[4] Jonathan Rose,et al. Approximate equations for forced-convection condensation in the presence of a non-condensing gas on a flat plate and horizontal tube , 1980 .
[5] S. Kim,et al. Fabrication and Characterization of the Capillary Performance of Superhydrophilic Cu Micropost Arrays , 2010, Journal of Microelectromechanical Systems.
[6] Frank P. Incropera,et al. Introduction to Heat Transfer -5/E. , 2008 .
[7] A. Abdel-azim. Fundamentals of Heat and Mass Transfer , 2011 .
[8] Evelyn N Wang,et al. Condensation on superhydrophobic surfaces: the role of local energy barriers and structure length scale. , 2012, Langmuir : the ACS journal of surfaces and colloids.
[9] John Henry J. Scott,et al. Three dimensional aspects of droplet coalescence during dropwise condensation on superhydrophobic surfaces , 2011 .
[10] John H. Lienhard,et al. Entropy generation in condensation in the presence of high concentrations of noncondensable gases , 2012 .
[11] Y. Chu,et al. Dynamical growth behavior of copper clusters during electrodeposition , 2010 .
[12] Konrad Rykaczewski,et al. Microdroplet growth mechanism during water condensation on superhydrophobic surfaces. , 2012, Langmuir : the ACS journal of surfaces and colloids.
[13] Maneesh K. Gupta,et al. Using amphiphilic nanostructures to enable long-range ensemble coalescence and surface rejuvenation in dropwise condensation. , 2012, ACS nano.
[14] Meng Hua,et al. Nanograssed Micropyramidal Architectures for Continuous Dropwise Condensation , 2011 .
[15] V. Carey. Liquid-Vapor Phase-Change Phenomena: An Introduction to the Thermophysics of Vaporization and Condensation Processes in Heat Transfer Equipment, Third Edition , 2020 .
[16] J. W. Gibbs,et al. Scientific Papers , 1997, Nature.
[17] Wei Sun,et al. Mechanism study of condensed drops jumping on super-hydrophobic surfaces , 2012 .
[18] Dimo Kashchiev,et al. Nucleation : basic theory with applications , 2000 .
[19] J. Higdon,et al. On the gravitational displacement of three-dimensional fluid droplets from inclined solid surfaces , 1999, Journal of Fluid Mechanics.
[20] H. Andrews,et al. Three-dimensional hierarchical structures for fog harvesting. , 2011, Langmuir : the ACS journal of surfaces and colloids.
[21] Di Gao,et al. Anti-icing superhydrophobic coatings. , 2009, Langmuir : the ACS journal of surfaces and colloids.
[22] Clark W. Bullard,et al. Air-side performance of brazed aluminum heat exchangers under dehumidifying conditions , 2002 .
[23] Y. Nam,et al. A comparative study of the morphology and wetting characteristics of micro/nanostructured Cu surfaces for phase change heat transfer applications , 2013 .
[24] E. Wang,et al. Liquid Evaporation on Superhydrophobic and Superhydrophilic Nanostructured Surfaces , 2011 .
[25] Dale E. Briggs,et al. The condensing of low pressure steam on vertical rows of horizontal copper and titanium tubes , 1966 .
[26] E. Wang,et al. Modeling and Optimization of Superhydrophobic Condensation , 2013 .
[27] J. Chinn,et al. Dynamics of nanoparticle self-assembly into superhydrophobic liquid marbles during water condensation. , 2011, ACS nano.
[28] Andrei G. Fedorov,et al. Visualization of droplet departure on a superhydrophobic surface and implications to heat transfer enhancement during dropwise condensation , 2010 .
[29] Evelyn N. Wang,et al. Condensation on superhydrophobic copper oxide nanostructures , 2012 .
[30] Ali Abbas,et al. Evaluation of using thermoelectric coolers in a dehumidification system to generate freshwater from ambient air , 2011 .
[31] A. Vosough,et al. IMPROVEMENT POWER PLANT EFFICIENCY WITH CONDENSER PRESSURE , 2011 .
[32] K. Rykaczewski,et al. Methodology for imaging nano-to-microscale water condensation dynamics on complex nanostructures. , 2011, ACS nano.
[33] Akili D. Khawaji,et al. Advances in seawater desalination technologies , 2008 .
[34] Evelyn N Wang,et al. Effect of droplet morphology on growth dynamics and heat transfer during condensation on superhydrophobic nanostructured surfaces. , 2012, ACS nano.
[35] T. J. McCarthy,et al. Self-Assembly Is Not the Only Reaction Possible between Alkyltrichlorosilanes and Surfaces: Monomolecular and Oligomeric Covalently Attached Layers of Dichloro- and Trichloroalkylsilanes on Silicon , 2000 .
[36] M. Georgelin,et al. Self-organized dendritic sidebranching in directional solidification: sidebranch coherence within uncorrelated bursts. , 2009, Physical review. E, Statistical, nonlinear, and soft matter physics.
[37] J. Rose. Dropwise condensation theory and experiment: A review , 2002 .
[38] János M. Beér,et al. High efficiency electric power generation: The environmental role , 2007 .
[39] A. Larsen,et al. Luminescence decay dynamics of self-assembled germanium islands in silicon , 2011 .
[40] N. K. Maheshwari,et al. Investigation on condensation in presence of a noncondensable gas for a wide range of Reynolds number , 2004 .
[41] Baizhan Li,et al. Urbanisation and its impact on building energy consumption and efficiency in China , 2009 .
[42] P. J. Marto,et al. Evaluation of organic coatings for the promotion of dropwise condensation of steam , 1986 .
[43] D. Quéré. Wetting and Roughness , 2008 .
[44] J. Boreyko,et al. Self-propelled dropwise condensate on superhydrophobic surfaces. , 2009, Physical review letters.
[45] Chongyoup Kim,et al. VISCOSITY AND THERMAL CONDUCTIVITY OF COPPER OXIDE NANOFLUID DISPERSED IN ETHYLENE GLYCOL , 2005 .
[46] A. Bejan. Fundamentals of exergy analysis, entropy generation minimization, and the generation of flow architecture , 2002 .
[47] S. Son,et al. Sub-micrometer dropwise condensation under superheated and rarefied vapor condition. , 2010, Langmuir : the ACS journal of surfaces and colloids.
[48] Xuehu Ma,et al. Condensation heat transfer enhancement in the presence of non-condensable gas using the interfacial effect of dropwise condensation , 2008 .
[49] D. Beysens,et al. Condensation-induced jumping water drops. , 2009, Physical review. E, Statistical, nonlinear, and soft matter physics.
[50] F. Blanchette,et al. Partial coalescence of drops at liquid interfaces , 2006 .
[51] E. Schmidt,et al. Versuche über die Kondensation von Wasserdampf in Film- und Tropfenform , 1930 .
[52] Y. Joshi,et al. ESEM Imaging of Condensation on a Nanostructured Superhydrophobic Surface , 2010 .
[53] M. Ferenets,et al. Thin Solid Films , 2010 .
[54] David H. Gracias,et al. Laser triggered sequential folding of microstructures , 2012 .
[55] S. Yao,et al. How nanorough is rough enough to make a surface superhydrophobic during water condensation , 2012 .
[56] Luis Pérez-Lombard,et al. A review on buildings energy consumption information , 2008 .
[57] W. Wu,et al. ON THE MECHANISM OF DROPWISE CONDENSATION , 1976 .
[58] Jiangtao Cheng,et al. Condensation heat transfer on two-tier superhydrophobic surfaces , 2012 .
[59] Yuejun Zhao,et al. Planar Jumping-Drop Thermal Diodes , 2011 .
[60] Ho-Young Kim,et al. Sliding of liquid drops down an inclined solid surface. , 2002, Journal of colloid and interface science.
[61] A. Fedorov,et al. Electron beam heating effects during environmental scanning electron microscopy imaging of water condensation on superhydrophobic surfaces , 2011 .