A kirigami approach to engineering elasticity in nanocomposites through patterned defects

Nature Materials

Volumn 14, Issue 8, 2015, Pages 785-789

  Shyu, Terry C ^a   Damasceno, Pablo F ^a   Dodd, Paul M ^a   Lamoureux, Aaron ^a   Xu, Lizhi ^a   Shlian, Matthew ^a   Shtein, Max ^a   Glotzer, Sharon C ^a   Kotov, Nicholas A ^a  

^a UNIVERSITY OF MICHIGAN   (United States)

Author keywords

[No Author keywords available]

Indexed keywords

ARTS COMPUTING; DEFECTS; ELASTICITY; ELECTRIC DISCHARGES; FINITE ELEMENT METHOD; NANOCOMPOSITES; NANOTECHNOLOGY; OPTOELECTRONIC DEVICES; STOCHASTIC SYSTEMS;

ELECTRICAL CONDUCTANCE; FINITE ELEMENT MODELLING; MULTIFUNCTIONALITY; PATTERNING TECHNIQUES; PLASMA ELECTRODES; STRETCHABLE CONDUCTORS; STRETCHABLE ELECTRONICS; TECHNOLOGICAL SOLUTION;

STRAIN;

CARBON NANOTUBE; NANOCOMPOSITE;

CHEMICAL ENGINEERING; CHEMISTRY; ELASTICITY; ELECTRIC CONDUCTIVITY; FINITE ELEMENT ANALYSIS; MECHANICAL STRESS; NANOTECHNOLOGY; PROCEDURES; SCANNING ELECTRON MICROSCOPY; THREE DIMENSIONAL PRINTING; ULTRASTRUCTURE;

CHEMICAL ENGINEERING; ELASTICITY; ELECTRIC CONDUCTIVITY; FINITE ELEMENT ANALYSIS; MICROSCOPY, ELECTRON, SCANNING; NANOCOMPOSITES; NANOTECHNOLOGY; NANOTUBES, CARBON; PRINTING, THREE-DIMENSIONAL; STRESS, MECHANICAL;

EID: 84938198374     PISSN: 14761122     EISSN: 14764660     Source Type: Journal    
DOI: 10.1038/nmat4327     Document Type: Article

References (30)

1. Khang, D-Y., et al Molecular scale buckling mechanics in individual aligned single-wall carbon nanotubes on elastomeric substrates. Nano Lett. 8, 124-130 (2008
2. Sekitani, T., et al. A rubberlike stretchable active matrix using elastic conductors. Science 321, 1468-1472 (2008
3. Zhang, Y., et al. Polymer-embedded carbon nanotube ribbons for stretchable conductors. Adv. Mater. 22, 3027-3031 (2010
4. Chun, K-Y., et al. Highly conductive, printable and stretchable composite films of carbon nanotubes and silver. Nature Nanotech. 5, 853-857 (2010
5. Kim, Y., et al. Stretchable nanoparticle conductors with self-organized conductive pathways. Nature 500, 59-64 (2013
6. Fratzl, P., & Weinkamer, R. Nature's hierarchical materials. Prog. Mater. Sci. 52, 1263-1334 (2007
7. Cranford, S.W., Tarakanova, A., Pugno, N. M., & Buehler, M. J. Nonlinear material behaviour of spider silk yields robust webs. Nature 482, 72-76 (2012
8. Meyers, M., McKittrick, J., & Chen, P. Structural biological materials: Critical mechanics-materials connections. Science 339, 773-779 (2013
9. Lee, P., et al. Highly stretchable or transparent conductor fabrication by a hierarchical multiscale hybrid nanocomposite. Adv. Funct. Mater. 24, 5671-5678 (2014
10. Khayer Dastjerdi, A., Rabiei, R., & Barthelat, F. The weak interfaces within tough natural composites: Experiments on three types of nacre. J. Mech. Behav. Biomed. Mater. 19, 50-60 (2013
11. Tang, Z., Kotov, N. A., Magonov, S., & Ozturk, B. Nanostructured artificial nacre. Nature Mater. 2, 413-418 (2003
12. Barthelat, F., & Rabiei, R. Toughness amplification in natural composites. J. Mech. Phys. Solids 59, 829-840 (2011
13. Bauer, J., Hengsbach, S., Tesari, I., Schwaiger, R., & Kraft, O. High-strength cellular ceramic composites with 3D microarchitecture. Proc. Natl Acad. Sci. USA 111, 2453-2458 (2014
14. Mirkhalaf, M., Dastjerdi, A. K., & Barthelat, F. Overcoming the brittleness of glass through bio-inspiration and micro-Architecture. Nature Commun. 5, 3166 (2014
15. Kim, J. Y., & Kotov, N. A. Charge transport dilemma of solution-processed nanomaterials. Chem. Mater. 26, 134-152 (2014
16. Jancar, J., et al. Current issues in research on structure-property relationships in polymer nanocomposites. Polymer 51, 3321-3343 (2010
17. Li, S. M., Kumar, N., & McKinley, G. H. High-performance elastomeric nanocomposites via solvent-exchange processing. Nature Mater. 6, 76-83 (2007
18. Vaia, R. A., & Wagner, H. D. Framework for nanocomposites. Mater. Today 7, 32-37 (November, 2004
19. Blees, M., Rose, P., Barnard, A., Roberts, S., & McEuen, P. L. Graphene Kirigami (2014); http://meetings.aps.org/link/BAPS.2014.MAR.L30.11
20. Castle, T., et al. Making the cut: Lattice kirigami rules. Phys. Rev. Lett. 113, 245502 (2014
21. Rossiter, J., & Sareh, S. in Proc. SPIE Vol. 9055 (ed. Lakhtakia, A.) 90550G (Bioinspiration, Biomimetics, and Bioreplication, 2014
22. Qi, Z., Park, H. S., & Campbell, D. K. Highly deformable graphene kirigami. Preprint at http://arxiv.org/abs/1407.8113 (2014
23. Silverberg, J. L., et al. Origami structures with a critical transition to bistability arising from hidden degrees of freedom. Nature Mater. 14, 389-393 (2015
24. Mullin, T., Deschanel, S., Bertoldi, K., & Boyce, M. Pattern transformation triggered by deformation. Phys. Rev. Lett. 99, 084301 (2007
25. Zhang, Y., et al One-step nanoscale assembly of complex structures via harnessing of an elastic instability. Nano Lett. 8, 1192-1196 (2008
26. Zhu, J., Zhang, H., & Kotov, N. A. Thermodynamic and structural insights into nanocomposites engineering by comparing two materials assembly techniques for graphene. ACS Nano 7, 4818-4829 (2013
27. Holmes, D. P., & Crosby, A. J. Snapping surfaces. Adv. Mater. 19, 3589-3593 (2007
28. Kang, S. H., et al. Buckling-induced reversible symmetry breaking and amplification of chirality using supported cellular structures. Adv. Mater. 25, 3380-3385 (2013
29. Paiva, M. C., et al. Mechanical and morphological characterization of polymer-carbon nanocomposites from functionalized carbon nanotubes. Carbon 42, 2849-2854 (2004
30. Shim, B. S., et al. Multiparameter structural optimization of single-walled carbon nanotube sti-ness, and toughness. ACS Nano 3, 1711-1722 (2009