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(12) United States Patent (10) Patent No.: US 8,535,791 B2 Dhinojwala Et Al

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(12) United States Patent (10) Patent No.: US 8,535,791 B2 Dhinojwala Et Al US008535791 B2 (12) United States Patent (10) Patent No.: US 8,535,791 B2 Dhinojwala et al. (45) Date of Patent: Sep. 17, 2013 (54) ALIGNED CARBON NANOTUBE-POLYMER (56) References Cited MATERIALS, SYSTEMS AND METHODS U.S. PATENT DOCUMENTS (75) Inventors: Ali Dhinojwala, Akron, OH (US); 2003. O165418 A1 9/2003 Ajayan et al. Pulickel M. Ajayan, Houston, TX (US); 2006.0068.195 A1 3/2006 Majumdar et al. Sunny Sethi, Akron, OH (US) 2006, OO78725 A1 4/2006 Fearing et al. 2006/0202355 A1* 9/2006 Majidi et al. .................. 257/783 (73) Assignees: The University of Akron, Akron, OH 2008/0128122 A1* 6/2008 Huang et al. .................. 165,185 (US); Rensselaer Polytechnical 2008/0292840 Al 1 1/2008 Majumdar et al. Institute, Troy, NY (US) FOREIGN PATENT DOCUMENTS JP 2007-536101 12/2007 (*) Notice: Subject to any disclaimer, the term of this patent is extended or adjusted under 35 OTHER PUBLICATIONS U.S.C. 154(b) by 1033 days. Sethi, et al., Gecko-Inspired Carbon Nanotube-Based Self-Cleaning (21) Appl. No.: 12/369,205 Adhesives, Nano Letters, published online Feb. 12, 2008.* Aligned Carbon Nanotube-Polymer Hybrid Architectures for Filed: Feb. 11, 2009 Diverse Flexible Electronic Applications, Yung Joon Jung et al., (22) Nano Letter, 2006, vol. 6, No. 3, pp. 413-418. (65) Prior Publication Data (Continued) US 2009/O26956O A1 Oct. 29, 2009 Primary Examiner — Matthew Matzek Related U.S. Application Data (74) Attorney, Agent, or Firm — Renner, Kenner, Greive, (63) Continuation-in-part of application No. 1 1/428,185, Bobak, Taylor & Weber filed on Jun. 30, 2006, now Pat. No. 7,927,666, and a continuation-in-part of application No. 1 1/675,442, (57) ABSTRACT filed on Feb. 15, 2007. Aligned carbon nanotube-polymer composite materials, sys (60) Provisional application No. 61/114,482, filed on Nov. tems and methods include a substrate that carries an adhesive 14, 2008. coating thereon. A plurality of carbon nanostructures are (51) Int. C. adhered to the substrate by the adhesive coating, such that the B32B5/02 (2006.01) nanostructures are formed into a predetermined architecture, such that the architecture of the nanostructures defines at least (52) U.S. C. one orientation for a plurality of nanostructures, and defies USPC ............. 428/220; 428/99: 428/221; 428/332; the approximate spacing between the nanostructures and/or 428/357; 428/364; 428/401; 442/85; 442/86; groups of nanostructures. The adherence of the carbon nano 977/742; 977/762; 977/773 structures in the adhesive coating stabilizes the predeter (58) Field of Classification Search mined architecture of the nanostructures, such that the archi USPC ................... 428/99, 141, 220, 221, 332, 343, tecture renders the composite material Superhydrophobic. 428/357, 364, 401, 402: 442/85, 86: 977/742, 977/762, 773 See application file for complete search history. 31 Claims, 14 Drawing Sheets US 8,535,791 B2 Page 2 (56) References Cited Zhang et al., Applied Physics Letters, vol. 77. No. 23, Dec. 4, 2000, pp. 3764-3766. OTHER PUBLICATIONS Interfacial energy and strength of multiwalled-carbon-nanotube based dry adhesive, Yang Zhao et al., J. Vac. Sci. Technol. B 24(1), Synthetic gecko foot-hairs from multiwalled carbon nanotubes, Betul Jan./Feb. 2006, 2006 American Vacuum Society, pp. 331-335. Yurdumakan et al., Chemical Communication. The Royal Society of Masarapu, Charan and Wei Bingqing, Direct Growth of Aligned Chemistry 2005, pp. 3799-3801. Multiwalled Carbon Nanotubes on Treated Stainless Steel Sub Temperature-Activated Interfacial Friction Damping in Carbon strates, American Chemical Society, 2007, pp. 9046-9049, vol. 23, Nanotube Polymer Composites, Jonghwan Suhr et al., Nano Letters, Langmuir, Newark, Delaware. 2006, vol. 6, No. 2, pp. 219-223. Lau, Kenneth K. S. et al., Superhydrophobic Carbon Nanotube For Bottom-Up Growth of Carbon Nanotube Multilayers: Unprec ests, Nano Letters, 2003, pp. 1701-1705, vol. 3, No. 12, Cambridge, edented Growth, Xuesong Lietal. Nano Letters, 2005, vol. 5, No. 10, MA. pp. 1997-2000. International Application No. PCT/US2009/064296 International Super-Compressible Foamlike Carbon Nanotube Films, Anyuan Search Report/Written Opinion, May 31, 2010, 12 pages. Cao, et al., Science, vol. 310, Nov. 25, 2005, pp. 1307-1310. Substrate-site selective growth of aligned carbon nanotubes, Z. J. * cited by examiner U.S. Patent Sep. 17, 2013 Sheet 1 of 14 US 8,535,791 B2 FIG. 1 FG, 4 U.S. Patent Sep. 17, 2013 Sheet 2 of 14 US 8,535,791 B2 ?INJ Z U.S. Patent Sep. 17, 2013 Sheet 3 of 14 US 8,535,791 B2 500 in OO im 5 (Im Sir FIG.SB Polymer tape C. aroon rsrce stee 18 F.G. 5C Synthetic gecko tape Viscoelastic tape O 200 400 600 800 Time (s) U.S. Patent Sep. 17, 2013 Sheet 4 of 14 US 8,535,791 B2 FIG. 6 2 24 d. Restowing excessive PDMS and citing F.G. 7 F.G. 8 FG ... O U.S. Patent Sep. 17, 2013 Sheet 5 of 14 US 8,535,791 B2 FG, 1A III it ( X s s Strain (%) U.S. Patent Sep. 17, 2013 Sheet 6 of 14 US 8,535,791 B2 F.G. 1B 8, 18 18 *:::::$38 hi::::: ::::::::::3 3.8 * {x38x333e E.3 Compression (%) U.S. Patent Sep. 17, 2013 Sheet 7 of 14 US 8,535,791 B2 F.G. 14 FG, 2. U.S. Patent Sep. 17, 2013 Sheet 8 of 14 US 8,535,791 B2 F.G. 13 Device Device 2 U.S. Patent Sep. 17, 2013 Sheet 9 of 14 US 8,535,791 B2 FIG 15A FIG. 15B FIG. 15C U.S. Patent Sep. 17, 2013 Sheet 10 of 14 US 8,535,791 B2 FIG 16 U.S. Patent Sep. 17, 2013 Sheet 11 of 14 US 8,535,791 B2 A. 29 FIG. 18A FIG. 18B U.S. Patent Sep. 17, 2013 Sheet 12 of 14 US 8,535,791 B2 FIG. 18C FIG. 18D U.S. Patent Sep. 17, 2013 Sheet 13 of 14 US 8,535,791 B2 FIG. 19A Shear Measurement s&x&x&884&sssssssssssssssssssssssssssssss Crities a - states 250 in sample with different treatinents FIG. 19B U.S. Patent Sep. 17, 2013 Sheet 14 of 14 US 8,535,791 B2 8 O m {) 2 O O O 5 O 15 2O Contact Area (mm?) FIG. 20 US 8,535,791 B2 1. 2 ALIGNED CARBON NANOTUBE-POLYMER It has also been noted that the external surfaces of many MATERIALS, SYSTEMS AND METHODS plants and animals have a rough surface structure combined with an ideal Surface chemistry to create self-cleaning, water This patent application is a continuation-in-part patent repellant surfaces. For example, the VdW interaction application claiming priority to U.S. patent application Ser. 5 between the hairs of the gecko and a substrate after contact No. 1 1/428,185 filed on Jun. 30, 2006 and U.S. patent appli may play a role in self-cleaning. Additionally, self-cleaning cation Ser. No. 1 1/675,442 filed Feb. 15, 2007 which is a characteristics are found on the leaf surface of the N. nucifera continuation-in-part of U.S. patent application Ser. No. (the white lotus) and the wing Surface of many insects, which 1 1/428,185 filed on Jun. 30, 2006 and U.S. Provisional Patent combine a topology describing a high degree of Surface Application Ser. No. 61/114,482 filed Nov. 14, 2008 which is 10 roughness with a chemistry that exhibits low Surface energy. a continuation-in part of U.S. patent application Ser. No. Such a combination creates a Superhydrophobic surface that 1 1/428,185 filed on Jun. 30, 2006, which are incorporated sheds liquids of various types, and allows particulates to be herein by reference in their entirety. removed when Subjected to an external force Such as rolling water droplets, or flowing air. It would be desirable to provide FIELD OF INVENTION 15 self-cleaning characteristics in association with adhesive type materials. Some other systems found in nature that exhibit The present invention relates to composite carbon nano self-cleaning properties include the leaves of the lotus and structures, such as nanotubes, adhered to an adhesive for lady's mantle plants. It has also been found that the For providing diverse systems for different applications, such as example, the self-cleaning characteristics found on the leaf dry adhesives, self-cleaning applications, electronic systems, 20 surface of the N. nucifera (the white lotus) and the wing display devices and other applications. The invention is also Surface of many insects combine atopology describing a high directed to methods for forming Such composite materials degree of Surface roughness with a chemistry that exhibits and for their use, including materials and products having low surface energy thus creating a Superhydrophobic Surface self-cleaning properties. Such that it sheds liquids of various types, allowing particu 25 lates to be removed when subjected to an external force such BACKGROUND OF THE INVENTION as rolling water droplet, or flowing air. The surface of the lotus leaves for example have two levels of microscopic roughness, The use and development of carbon nanotubes has which along with a hydrophobic wax coating, render the lotus expanded, as these materials have shown to be valuable in leaves Superhydrophobic. A water droplet, when placed on next generation industries including the fields of electronics 30 the Surface of a lotus leaf forms a large contactangle with low and chemistry. The further development of carbon nanotube contact angle hysteresis. This results in the water droplets technology allows organized structures or intertwined ran rolling off the leaf surface, leaving the surface clean.
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