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Superhydrophobic carbon-based materials: a review of synthesis, structure, and applications
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  • Journal title : Carbon letters
  • Volume 15, Issue 2,  2014, pp.89-104
  • Publisher : Korean Carbon Society
  • DOI : 10.5714/CL.2014.15.2.089
 Title & Authors
Superhydrophobic carbon-based materials: a review of synthesis, structure, and applications
Meng, Long-Yue; Park, Soo-Jin;
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Materials with appropriate surface roughness and low surface energy can form superhydrophobic surfaces, displaying water contact angles greater than . Superhydrophobic carbon-based materials are particularly interesting due to their exceptional physicochemical properties. This review discusses the various techniques used to produce superhydrophobic carbon-based materials such as carbon fibers, carbon nanotubes, graphene, amorphous carbons, etc. Recent advances in emerging fields such as energy, environmental remediation, and thermal management in relation to these materials are also discussed.
superhydrophobicity;carbon-based materials;surface energy;surface roughness;
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Qiao R, Zhang R, Zhu W, Gong P. Lab simulation of profile modification and enhanced oil recovery with a quaternary ammonium cationic polymer. J Ind Eng Chem, 18, 111 (2012). crossref(new window)

Lafuma A, Quere D. Superhydrophobic states. Nat Mater, 2, 457 (2003). crossref(new window)

Feng XJ, Jiang L. Design and creation of superwetting/antiwetting surfaces. Adv Mater, 18, 3063 (2006). crossref(new window)

Fei T, Chen H, Lin J. Transparent superhydrophobic films possessing high thermal stability and improved moisture resistance from the deposition of MTMS-based aerogels. Colloids Surf Physicochem Eng Aspects, 443, 255 (2014). crossref(new window)

Wolfs M, Darmanin T, Guittard F. Superhydrophobic fibrous polymers. Polym Rev, 53, 460 (2013). crossref(new window)

Fowkes FM, Zisman WA. Contact Angle, Wettability, and Adhesion (Advances in Chemistry Series Vol. 43), American Chemical Society, Washington, DC (1964).

Johnson RE, Dettre RH. Contact angle hysteresis. In: Fowkes FM, Zisman WA, eds. Contact Angle, Wettability, and Adhesion (Advances in Chemistry Series Vol. 43), American Chemical Society, Washington, DC, 112 (1964). crossref(new window)

Ahn CH, Baek Y, Lee C, Kim SO, Kim S, Lee S, Kim SH, Bae SS, Park J, Yoon J. Carbon nanotube-based membranes: fabrication and application to desalination. J Ind Eng Chem, 18, 1551 (2012). crossref(new window)

Barthlott W, Ehler N. Raster-Elektronenmikroskopie der Epidermis-Oberflachen von Spermatophyten (Tropische und subtropische Pflanzenwelt Vol. 19), Akademie der Wiss. u.d. Literatur, Mainz (1977).

Quere D. Rough ideas on wetting. Physica A, 313, 32 (2002). crossref(new window)

Celia E, Darmanin T, Taffin de Givenchy E, Amigoni S, Guittard F. Recent advances in designing superhydrophobic surfaces. J Colloid Interface Sci, 402, 1 (2013). crossref(new window)

Yong J, Yang Q, Chen F, Zhang D, Du G, Bian H, Si J, Yun F, Hou X. Superhydrophobic PDMS surfaces with three-dimensional (3D) pattern-dependent controllable adhesion. Appl Surf Sci, 288, 579 (2014). crossref(new window)

Taylor P. The wetting of leaf surfaces. Curr Opin Colloid Interface Sci, 16, 326 (2011). crossref(new window)

Shirtcliffe NJ, McHale G, I. Newton M. The superhydrophobicity of polymer surfaces: Recent developments. J Polym Sci B, 49, 1203 (2011). crossref(new window)

Hassan AF, Youssef AM, Priecel P. Removal of deltamethrin insecticide over highly porous activated carbon prepared from pistachio nutshells. Carbon Lett, 14, 234 (2013). crossref(new window)

Song YI, Lee JW, Kim TY, Jung HJ, Jung YC, Suh SJ, Yang CM. Performance-determining factors in flexible transparent conducting single-wall carbon nanotube film. Carbon Lett, 14, 255 (2013). crossref(new window)

Kim SG, Park OK, Lee JH, Ku BC. Layer-by-layer assembled graphene oxide films and barrier properties of thermally reduced graphene oxide membranes. Carbon Lett, 14, 247 (2013). crossref(new window)

Choi WK, Kim BJ, Park SJ. Fiber surface and electrical conductivity of electroless Ni-plated PET ultra-fine fibers. Carbon Lett, 14, 243 (2013). crossref(new window)

Li B, Zhao Z, Gao F, Wang X, Qiu J. Mesoporous microspheres composed of carbon-coated $TiO_2$ nanocrystals with exposed {0 0 1} facets for improved visible light photocatalytic activity. Appl Catal B, 147, 958 (2014). crossref(new window)

Jain A, Jayaraman S, Balasubramanian R, Srinivasan MP. Hydrothermal pre-treatment for mesoporous carbon synthesis: enhancement of chemical activation. J Mater Chem A, 2, 520 (2014). crossref(new window)

Wu D, Li Y, Zhang Y, Wang P, Wei Q, Du B. Sensitive electrochemical sensor for simultaneous determination of dopamine, ascorbic acid, and uric acid enhanced by amino-group functionalized mesoporous $Fe_3O_4$@graphene sheets. Electrochim Acta, 116, 244 (2014). crossref(new window)

Zhu Z, Hu Y, Jiang H, Li C. A three-dimensional ordered mesoporous carbon/carbon nanotubes nanocomposites for supercapacitors. J Power Sources, 246, 402 (2014). crossref(new window)

Tao G, Zhang L, Hua Z, Chen Y, Guo L, Zhang J, Shu Z, Gao J, Chen H, Wu W, Liu Z, Shi J. Highly efficient adsorbents based on hierarchically macro/mesoporous carbon monoliths with strong hydrophobicity. Carbon, 66, 547 (2014). crossref(new window)

Liu J, Yang T, Wang DW, Lu GQ, Zhao D, Qiao SZ. A facile soft-template synthesis of mesoporous polymeric and carbonaceous nanospheres. Nat Commun, 4, 2798 (2013). crossref(new window)

Kim JM, Song IS, Cho D, Hong I. Effect of carbonization temperature and chemical pre-treatment on the thermal change and fiber morphology of kenafbased carbon fibers. Carbon Lett, 12, 131 (2011). crossref(new window)

Lee S, Kim J, Ku BC, Kim J, Chung Y. Effect of process condition on tensile properties of carbon fiber. Carbon Lett, 12, 26 (2011). crossref(new window)

Asghar HMA, Hussain SN, Roberts EPL, Campen AK, Brown NW. Pre-treatment of adsorbents for waste water treatment using adsorption coupled-with electrochemical regeneration. J Ind Eng Chem, 19, 1689 (2013). crossref(new window)

Han M, Yun J, Kim HI, Lee YS. Effect of surface modification of graphene oxide on photochemical stability of poly(vinyl alcohol)/graphene oxide composites. J Ind Eng Chem, 18, 752 (2012). crossref(new window)

Cho D, Yoon SB, Cho CW, Park JK. Effect of additional heat-treatment temperature on chemical, microstructural, mechanical, and electrical properties of commercial PAN-based carbon fibers. Carbon Lett, 12, 223 (2011). crossref(new window)

Chen Z, Dong L, Yang D, Lu H. Superhydrophobic graphenebased materials: surface construction and functional applications. Adv Mater, 25, 5352 (2013). crossref(new window)

Nguyen DD, Tai NH, Lee SB, Kuo WS. Superhydrophobic and superoleophilic properties of graphene-based sponges fabricated using a facile dip coating method. Energy Environ Sci, 5, 7908 (2012). crossref(new window)

Zheng L, Li Z, Bourdo S, Khedir KR, Asar MP, Ryerson CC, Biris AS. Exceptional superhydrophobicity and low velocity impact icephobicity of acetone-functionalized carbon nanotube films. Langmuir, 27, 9936 (2011). crossref(new window)

Bayer IS, Steele A, Loth E. Superhydrophobic and electroconductive carbon nanotube-fluorinated acrylic copolymer nanocomposites from emulsions. Chem Eng J, 221, 522 (2013). http:// crossref(new window)

Yao L, He J. Recent progress in antireflection and self-cleaning technology: from surface engineering to functional surfaces. Prog Mater Sci, 61, 94 (2014). crossref(new window)

Zhou Y, Wang B, Song X, Li E, Li G, Zhao S, Yan H. Control over the wettability of amorphous carbon films in a large range from hydrophilicity to super-hydrophobicity. Appl Surf Sci, 253, 2690 (2006). crossref(new window)

Chen CH, Cai Q, Tsai C, Chen CL, Xiong G, Yu Y, Ren Z. Dropwise condensation on superhydrophobic surfaces with two-tier roughness. Appl Phys Lett, 90, 173108 (2007). crossref(new window)

Li Y, Huang XJ, Heo SH, Li CC, Choi YK, Cai WP, Cho SO. Superhydrophobic bionic surfaces with hierarchical microsphere/SWCNT composite arrays. Langmuir, 23, 2169 (2006). crossref(new window)

Wang Z, Lopez C, Hirsa A, Koratkar N. Impact dynamics and rebound of water droplets on superhydrophobic carbon nanotube arrays. Appl Phys Lett, 91, 023105 (2007). crossref(new window)

Zhou XH, Cui GL, Zhi LJ, Zhang SS. Large-area helical carbon microcoils with superhydropho-bicity over a wide range of pH values. New Carbon Mater, 22, 1 (2007). crossref(new window)

Hsieh CT, Chen WY, Wu FL. Fabrication and superhydrophobicity of fluorinated carbon fabrics with micro/nanoscaled two-tier roughness. Carbon, 46, 1218 (2008). crossref(new window)

Hsieh CT, Wu FL, Yang SY. Superhydrophobicity from composite nano/microstructures: carbon fabrics coated with silica nanoparticles. Surf Coat Technol, 202, 6103 (2008). crossref(new window)

Li J, Sambandam S, Lu W, Lukehart CM. Carbon nanofibers "spot-welded" to carbon felt: a mechanically stable, bulk mimic of lotus leaves. Adv Mater, 20, 420 (2008). crossref(new window)

Luo C, Zuo X, Wang L, Wang E, Song S, Wang J, Wang J, Fan C, Cao Y. Flexible carbon nanotube: polymer composite films with high conductivity and superhydrophobicity made by solution process. Nano Lett, 8, 4454 (2008). crossref(new window)

Ma M, Hill RM, Rutledge GC. A review of recent results on superhydrophobic materials based on micro- and nanofibers. J Adhes Sci Technol, 22, 1799 (2008). crossref(new window)

Srinivasan S, Praveen VK, Philip R, Ajayaghosh A. Bioinspired superhydrophobic coatings of carbon nanotubes and linear ${\pi}$ systems based on the "bottom-up" self-assembly approach. Angew Chem Int Ed, 47, 5750 (2008). crossref(new window)

Wang N, Xi J, Wang S, Liu H, Feng L, Jiang L. Long-term and thermally stable superhydrophobic surfaces of carbon nanofibers. J Colloid Interface Sci, 320, 365 (2008). crossref(new window)

Xiao X, Cheng YT, Sheldon BW, Rankin J. Condensed water on superhydrophobic carbon films. J Mater Res, 23, 2174 (2008). crossref(new window)

Zou J, Chen H, Chunder A, Yu Y, Huo Q, Zhai L. Preparation of a superhydrophobic and conductive nanocomposite coating from a carbon-nanotube-conjugated block copolymer dispersion. Adv Mater, 20, 3337 (2008). crossref(new window)

Bai BC, Cho S, Yu HR, Yi KB, Kim KD, Lee YS. Effects of aminated carbon molecular sieves on breakthrough curve behavior in $CO_2/CH_4$ separation. J Ind Eng Chem, 19, 776 (2013). crossref(new window)

Ghaedi M, Montazerozohori M, Sajedi M, Roosta M, Nickoosiar Jahromi M, Asghari A. Comparison of novel sorbents for preconcentration of metal ions prior to their flame atomic absorption spectrometry determination. J Ind Eng Chem, 19, 1781 (2013). crossref(new window)

Ghaedi M, Montazerozohori M, Rahimi N, Biysreh MN. Chemically modified carbon nanotubes as efficient and selective sorbent for enrichment of trace amount of some metal ions. J Ind Eng Chem, 19, 1477 (2013). crossref(new window)

Charinpanitkul T, Suthabanditpong W, Watanabe H, Shirai T, Faungnawakij K, Viriya-empikul N, Fuji M. Improved hydrophilicity of zinc oxide-incorporated layer-by-layer polyelectrolyte film fabricated by dip coating method. J Ind Eng Chem, 18, 1441 (2012). crossref(new window)

Bai BC, Kim JG, Im JS, Jung SC, Lee YS. Influence of oxyfluorination on activated carbon nanofibers for $CO_2$ storage. Carbon Lett, 12, 236 (2011). crossref(new window)

Park SJ, Lee HY. Effect of atmospheric-pressure plasma on adhesion characteristics of polyimide film. J Colloid Interface Sci, 285, 267 (2005). crossref(new window)

Chauhan NPS. Structural and thermal characterization of macrobranched functional terpolymer containing 8-hydroxyquinoline moieties with enhancing biocidal properties. J Ind Eng Chem, 19, 1014 (2013). crossref(new window)

Heo GY, Yoo YJ, Park SJ. Effect of carbonization temperature on electrical conductivity of carbon papers prepared from petroleum pitch-coated glass fibers. J Ind Eng Chem, 19, 1040 (2013). crossref(new window)

Lee JH, Kim IJ, Park SJ. Preparation and electrochemical behaviors of styrene-acrylonitrile-based porous carbon electrodes. Electrochim Acta, 113, 23 (2013). crossref(new window)

Jin FL, Ma CJ, Park SJ. Thermal and mechanical interfacial properties of epoxy composites based on functionalized carbon nanotubes. Mater Sci Eng A, 528, 8517 (2011). crossref(new window)

Bikshapathi M, Verma N, Singh RK, Joshi HC, Srivastava A. Preparation of activated carbon fibers from cost effective commercial textile grade acrylic fibers. Carbon Lett, 12, 44 (2011). crossref(new window)

Abdullah ID, Girgis BS, Tmerek YM, Badawy EH. Potential of activated carbon derived from local common reed in the refining of raw cane sugar. Carbon Lett, 11, 192 (2011). crossref(new window)

Kaneko K, Arai M, Yamamoto M, Ohba T, Miyamoto JI, Kim DY, Tao Y, Yang CM, Urita K, Fujimori T, Tanaka H, Ohkubo T, Utsumi S, Hattori Y, Konishi T, Fujikawa T, Kanoh H, Yudasaka M, Hata K, Yumura M, Iijima S, Muramatsu H, Hayashi T, Kim YA, Endo M. Fundamental understanding of nanoporous carbons for energy application potentials. Carbon Lett, 10, 177 (2009). crossref(new window)

Lee SY, Park SJ. $TiO_2$ photocatalyst for water treatment applications. J Ind Eng Chem, 19, 1761 (2013). crossref(new window)

Lee SY, Yop Rhee K, Nahm SH, Park SJ. Effect of p-type multi-walled carbon nanotubes for improving hydrogen storage behaviors. J Solid State Chem, 210, 256 (2014). crossref(new window)

Mao C, Liang C, Luo W, Bao J, Shen J, Hou X, Zhao W. Preparation of lotus-leaf-like polystyrene micro- and nanostructure films and its blood compatibility. J Mater Chem, 19, 9025 (2009). crossref(new window)

Barthlott W, Neinhuis C. Purity of the sacred lotus, or escape from contamination in biological surfaces. Planta, 202, 1 (1997). crossref(new window)

Neinhuis C, Barthlott W. Characterization and distribution of water-repellent, self-cleaning plant surfaces. Ann Bot, 79, 667 (1997). crossref(new window)

Feng L, Li S, Li Y, Li H, Zhang L, Zhai J, Song Y, Liu B, Jiang L, Zhu D. Super-hydrophobic surfaces: from natural to artificial. Adv Mater, 14, 1857 (2002). crossref(new window)

Jin M, Feng X, Feng L, Sun T, Zhai J, Li T, Jiang L. Superhydrophobic aligned polystyrene nanotube films with high adhesive force. Adv Mater, 17, 1977 (2005). crossref(new window)

Wenzel RN. Resistance of solid surfaces to wetting by water. Ind Eng Chem, 28, 988 (1936). crossref(new window)

Cassie ABD, Baxter S. Wettability of porous surfaces. Trans Faraday Soc, 40, 546 (1944). crossref(new window)

Wang J, Chen H, Sui T, Li A, Chen D. Investigation on hydrophobicity of lotus leaf: experiment and theory. Plant Sci, 176, 687 (2009). crossref(new window)

Yu Y, Zhao ZH, Zheng QS. Mechanical and superhydrophobic stabilities of two-scale surfacial structure of lotus leaves. Langmuir, 23, 8212 (2007). crossref(new window)

Robinson A. The Last Man Who Knew Everything: Thomas Young, the Anonymous Polymath Who Proved Newton Wrong, Explained How We See, Cured the Sick, and Deciphered the Rosetta Stone, Among Other Feats of Genius, Pi Press, New York, NY (2006).

Lee MW, An S, Latthe SS, Lee C, Hong S, Yoon SS. Electrospun polystyrene nanofiber membrane with superhydrophobicity and superoleophilicity for selective separation of water and low viscous oil. ACS Appl Mater Interfaces, 5, 10597 (2013). crossref(new window)

Chang CH, Hsu MH, Weng CJ, Hung WI, Chuang TL, Chang KC, Peng CW, Yen YC, Yeh JM. 3D-bioprinting approach to fabricate superhydrophobic epoxy/organophilic clay as an advanced anticorrosive coating with the synergistic effect of superhydrophobicity and gas barrier properties. J Mater Chem A, 1, 13869 (2013). crossref(new window)

Gupta N, Kavya MV, Singh YRG, Jyothi J, Barshilia HC. Superhydrophobicity on transparent fluorinated ethylene propylene films with nano-protrusion morphology by Ar + $O_2$ plasma etching: study of the degradation in hydrophobicity after exposure to the environment. J Appl Phys, 114, 164307 (2013). crossref(new window)

Yu E, Lee HJ, Ko TJ, Kim SJ, Lee KR, Oh KH, Moon MW. Hierarchical structures of AlOOH nanoflakes nested on Si nanopillars with anti-reflectance and superhydrophobicity. Nanoscale, 5, 10014 (2013). crossref(new window)

Wu J, Li J, Deng B, Jiang H, Wang Z, Yu M, Li L, Xing C, Li Y. Self-healing of the superhydrophobicity by ironing for the abrasion durable superhydrophobic cotton fabrics. Sci Rep, 3, 2951 (2013). crossref(new window)

Cao L, Liu J, Xu S, Xia Y, Huang W, Li Z. Inherent superhydrophobicity of Sn/SnOx films prepared by surface self-passivation of electrodeposited porous dendritic Sn. Mater Res Bull, 48, 4804 (2013). crossref(new window)

Timonen JV, Latikka M, Ikkala O, Ras RH. Free-decay and resonant methods for investigating the fundamental limit of superhydrophobicity. Nat Commun, 4, 2398 (2013). crossref(new window)

Meng LY, Rhee KY, Park SJ. Enhancement of superhydrophobicity and conductivity of carbon nanofibers-coated glass fabrics. J Ind Eng Chem, 2014 in press. crossref(new window)

Wang S, Song Y, Jiang L. Photoresponsive surfaces with controllable wettability. J Photochem Photobiol C, 8, 18 (2007). crossref(new window)

Barthlott W, Schimmel T, Wiersch S, Koch K, Brede M, Barczewski M, Walheim S, Weis A, Kaltenmaier A, Leder A, Bohn HF. The Salvinia paradox: superhydrophobic surfaces with hydrophilic pins for air retention under water. Adv Mater, 22, 2325 (2010). crossref(new window)

Cui XS, Li W. On the possibility of superhydrophobic behavior for hydrophilic materials. J Colloid Interface Sci, 347, 156 (2010). crossref(new window)

Marmur A. From hygrophilic to superhygrophobic: theoretical conditions for making high-contact-angle surfaces from low-contact-angle materials. Langmuir, 24, 7573 (2008). crossref(new window)

Liu JL, Feng XQ, Wang G, Yu SW. Mechanisms of superhydrophobicity on hydrophilic substrates. J Phys: Condens Matter, 19, 356002 (2007). crossref(new window)

Herminghaus S. Roughness-induced non-wetting. Europhys Lett, 52, 165 (2000). crossref(new window)

Zhang X, Shi F, Niu J, Jiang Y, Wang Z. Superhydrophobic surfaces: from structural control to functional application. J Mater Chem, 18, 621 (2008). crossref(new window)

Wang FJ, Li CQ, Tan ZS, Li W, Ou JF, Xue MS. PVDF surfaces with stable superhydrophobicity. Surf Coat Technol, 222, 55 (2013). crossref(new window)

Liu H, Zhai J, Jiang L. Wetting and anti-wetting on aligned carbon nanotube films. Soft Matter, 2, 811 (2006). crossref(new window)

Park SJ, Brendle M. London dispersive component of the surface free energy and surface enthalpy. J Colloid Interface Sci, 188, 336 (1997). crossref(new window)

Park SJ, Seo MK. Solid-liquid interface. Interface Sci Technol, 18, 147 (2011). crossref(new window)

Fowkes FM. Determination of interfacial tensions, contact angles, and dispersion forces in surfaces by assuming additivity of intermolecular interactions in surfaces. J Phys Chem, 66, 382 (1962). crossref(new window)

Fowkes FM. Additivity of intermolecular forces at interfaces. I. Determination of the contribution to surface and interfacial tensions of dispersion forces in various liquids. J Phys Chem, 67, 2538 (1963). crossref(new window)

Park SJ, Cho MS, Lee JR. Studies on the surface free energy of carbon-carbon composites: effect of filler addition on the ILSS of composites. J Colloid Interface Sci, 226, 60 (2000). crossref(new window)

Mironov VS, Kim SY, Park M. Electrical properties of polyethylene composite films filled with nickel powder and short carbon fiber hybrid filler. Carbon Lett, 14, 105 (2013). crossref(new window)

Zhu J, Park SW, Joh HI, Kim HC, Lee S. Preparation and characterization of isotropic pitch-based carbon fiber. Carbon Lett, 14, 94 (2013). crossref(new window)

Jin FL, Lee SY, Park SJ. Polymer matrices for carbon fiber-reinforced polymer composites. Carbon Lett, 14, 76 (2013). crossref(new window)

Choi KE, Seo MK. A study on the preparation of the eco-friendly carbon fibers-reinforced composites. Carbon Lett, 14, 58 (2013). crossref(new window)