[1] Noh, J. S. (2016). Conductive elastomers for stretchable electronics, sensors and energy harvesters. Polymers, 8(4), 123.
[2] Woo, J. Y., Kim, K. K., Lee, J., Kim, J. T., & Han, C. S. (2014). Highly conductive and stretchable Ag nanowire/carbon nanotube hybrid conductors. Nanotechnology, 25(28), 285203.
[3] Zhang, S., Li, Y., Tian, Q., Liu, L., Yao, W., Chi, C., ... & Wu, W. (2018). Highly conductive, flexible and stretchable conductors based on fractal silver nanostructures. Journal of Materials Chemistry C, 6(15), 3999-4006.
[4] Shin, M. K., Oh, J., Lima, M., Kozlov, M. E., Kim, S. J., & Baughman, R. H. (2010). Elastomeric conductive composites based on carbon nanotube forests. Advanced materials, 22(24), 2663-2667.
[5] Cai, L., Zhang, S., Miao, J., Yu, Z., & Wang, C. (2016). Fully printed stretchable thin-film transistors and integrated logic circuits. Acs Nano, 10(12), 11459-11468.
[6] Kim, K. S., Zhao, Y., Jang, H., Lee, S. Y., Kim, J. M., Kim, K. S., ... & Hong, B. H. (2009). Large-scale pattern growth of graphene films for stretchable transparent electrodes. nature, 457(7230), 706-710.
[7] Stankovich, S., Dikin, D. A., Dommett, G. H., Kohlhaas, K. M., Zimney, E. J., Stach, E. A., ... & Ruoff, R. S. (2006). Graphene-based composite materials. nature, 442(7100), 282-286.
[8] Yan, C., Wang, J., Kang, W., Cui, M., Wang, X., Foo, C. Y., ... & Lee, P. S. (2014). Highly stretchable piezoresistive graphene–nanocellulose nanopaper for strain sensors. Advanced materials, 26(13), 2022-2027.
[9] Chen, M., Zhang, L., Duan, S., Jing, S., Jiang, H., & Li, C. (2014). Highly stretchable conductors integrated with a conductive carbon nanotube/graphene network and 3D porous poly (dimethylsiloxane). Advanced Functional Materials, 24(47), 7548-7556.
[10] Yakuphanoglu, F., & Şenkal, B. F. (2007). Electronic and thermoelectric properties of polyaniline organic semiconductor and electrical characterization of Al/PANI MIS diode. The Journal of Physical Chemistry C, 111(4), 1840-1846.
[11] Fu, Y., & Manthiram, A. (2012). Enhanced cyclability of lithium–sulfur batteries by a polymer acid-doped polypyrrole mixed ionic–electronic conductor. Chemistry of Materials, 24(15), 3081-3087.
[12] Borah, D., Ozmen, M., Rasappa, S., Shaw, M. T., Holmes, J. D., & Morris, M. A. (2013). Molecularly functionalized silicon substrates for orientation control of the microphase separation of PS-b-PMMA and PS-b-PDMS block copolymer systems. Langmuir, 29(9), 2809-2820.
[13] C.AArnold, J.D. Summers, Y.P Chen, R.H Bott, D.Chen Polymer; Elsevier, 1989, Vol. 30, pp 986–995.
[14] Mahoney, C. M., Gardella, J. A., & Rosenfeld, J. C. (2002). Surface characterization and adhesive properties of poly (imidesiloxane) copolymers containing multiple siloxane segment lengths. Macromolecules, 35(13), 5256-5266..
[15] E.Hamciuc,C. Hamciuc, & Cazacu, ,Rev Roum Chim, . 2009 54, 1007-13.56-16.
[16] McGrath, J. E., Dunson, D. L., Mecham, S. J., & Hedrick, J. L. In Progress in Polyimide Chemistry I 1999 (pp. 61-105). Springer, Berlin, Heidelberg.
(17) M. Freebody,. (Ed.). 2011. Photonics Spectra, 45(5), 45-47.
(18) Borah, D., Ozmen, M., Rasappa, S., Shaw, M. T., Holmes, J. D., & Morris, M. A. (2013). Molecularly functionalized silicon substrates for orientation control of the microphase separation of PS-b-PMMA and PS-b-PDMS block copolymer systems. Langmuir, 29(9), 2809-2820.
(19) Mack, C. A. (2011). Fifty years of Moore's law. IEEE Transactions on semiconductor manufacturing, 24(2), 202-207..
(20) Raquez, J. M., Habibi, Y., Murariu, M., & Dubois, P. (2013). Polylactide (PLA)-based nanocomposites. Progress in Polymer Science, 38(10-11), 1504-1542.
[21] A.Vaglio Pret, P. Poliakov ,R. Gronheid, P Blomme, M. Miranda Corbalan,W Dehaene, D. Verkest, J. Van Houdt,D. ..(2012) Microelectronic Engineering; Elsevier, Vol. 98, pp 24–2804.013.
[22] Biswas, A., Bayer, I. S., Biris, A. S., Wang, T., Dervishi, E., & Faupel, F. (2012). Advances in top–down and bottom–up surface nanofabrication: Techniques, applications & future prospects. Advances in colloid and interface science, 170(1-2), 2-27.
[23] Darling, S. B. (2007). Directing the self-assembly of block copolymers. Progress in Polymer Science, 32(10), 1152-1204.
[24] Li, H. W., & Huck, W. T. (2004). Ordered block-copolymer assembly using nanoimprint lithography. Nano Letters, 4(9), 1633-1636.
[25] Kim, J. U., Lee, S., & Kim, T. I. (2016). Recent advances in unconventional lithography for challenging 3D hierarchical structures and their applications. Journal of Nanomaterials, 2016.
[26] Ghoshal, T., Senthamaraikannan, R., Shaw, M. T., Holmes, J. D., & Morris, M. A. (2012). “In situ” hard mask materials: a new methodology for creation of vertical silicon nanopillar and nanowire arrays. Nanoscale, 4(24), 7743-7750.
[27] Hirai, T., Leolukman, M., Liu, C. C., Han, E., Kim, Y. J., Ishida, Y., ... & Gopalan, P. (2009). One‐step direct‐patterning template utilizing self‐assembly of POSS‐containing block copolymers. Advanced Materials, 21(43), 4334-4338.
[28] Lee, J., Lee, P., Lee, H., Lee, D., Lee, S. S., & Ko, S. H. (2012). Very long Ag nanowire synthesis and its application in a highly transparent, conductive and flexible metal electrode touch panel. Nanoscale, 4(20), 6408-6414.
[29] Xu, F., & Zhu, Y. (2012). Highly conductive and stretchable silver nanowire conductors. Advanced materials, 24(37), 5117-5122.
[30] Gaynor, W., Burkhard, G. F., McGehee, M. D., & Peumans, P. (2011). Smooth nanowire/polymer composite transparent electrodes. Advanced Materials, 23(26), 2905-2910.
[31] Arnold, C. A., Summers, J. D., Chen, Y. P., Bott, R. H., Chen, D., & McGrath, J. E. (1989). Structure-property behaviour of soluble polyimide-polydimethylsiloxane segmented copolymers. Polymer, 30(6), 986-995.
[32] Mahoney, C. M., Gardella, J. A., & Rosenfeld, J. C. (2002). Surface characterization and adhesive properties of poly (imidesiloxane) copolymers containing multiple siloxane segment lengths. Macromolecules, 35(13), 5256-5266.
[33] Hamciuc, E., Hamciuc, C., & Cazacu, M. (2009). Comparative evaluation of some properties of two poly (ether-imide) thin films with/without fluorine in the structure. Rev Roum Chim, 54, 1007-1013.
[34] McGrath, J. E., Dunson, D. L., Mecham, S. J., & Hedrick, J. L. (1999). Synthesis and characterization of segmented polyimide-polyorganosiloxane copolymers. Progress in Polyimide Chemistry I, 61-105.
[35] Chen, G., Pei, X., Liu, J., & Fang, X. (2013). Synthesis and properties of transparent polyimides derived from trans-and cis-1, 4-bis (3, 4-dicarboxyphenoxy) cyclohexane dianhydrides. Journal of Polymer Research, 20(6), 1-11.
[36] Krea, M., Roizard, D., Moulai-Mostefa, N., & Sacco, D. (2004). New copolyimide membranes with high siloxane content designed to remove polar organics from water by pervaporation. Journal of Membrane Science, 241(1), 55-64.
[37] Wohl, C. J., Atkins, B. M., Belcher, M. A., & Connell, J. W. (2012). Synthesis, characterization, topographical modification, and surface properties of copoly (imide siloxane) s. High Performance Polymers, 24(1), 40-49.
[38] Yilgör, İ., & McGrath, J. E. (1988). Polysiloxane containing copolymers: a survey of recent developments. Polysiloxane copolymers/anionic polymerization, 1-86.
[39] Liaw, W. C., Chang-Chien, J., Kang, H., Cheng, Y. L., & Li-Wen, F. U. (2008). A straightforward synthesis and characterization of a new poly (imide siloxane)-based thermoplastic elastomer. Polymer journal, 40(2), 116-125.
[40] Mata, A., Fleischman, A. J., & Roy, S. (2005). Characterization of polydimethylsiloxane (PDMS) properties for biomedical micro/nanosystems. Biomedical microdevices, 7(4), 281-293. [41] Baughman, R. H., Zakhidov, A. A., & De Heer, W. A. (2002). Carbon nanotubes--the route toward applications. science, 297(5582), 787-792.
[42] Lee, S. H., Lee, D. H., Lee, W. J., & Kim, S. O. (2011). Tailored assembly of carbon nanotubes and graphene. Advanced Functional Materials, 21(8), 1338-1354.
[43] Jiao, J., Zhang, H., Yu, L., Wang, X., & Wang, R. (2012). Dispersion of carbon nanotubes with the aid of surface-active ionic liquids 1-dodecyl-3-methyl-pyrrolidinium bromide. Journal of Molecular Liquids, 171, 6-10.
[44] Coleman, J. N., Khan, U., Blau, W. J., & Gun’ko, Y. K. (2006). Small but strong: a review of the mechanical properties of carbon nanotube–polymer composites. Carbon, 44(9), 1624-1652.
[45] Mirkhani, S. A., Arjmand, M., Sadeghi, S., Krause, B., Pötschke, P., & Sundararaj, U. (2017). Impact of synthesis temperature on morphology, rheology and electromagnetic interference shielding of CVD-grown carbon nanotube/polyvinylidene fluoride nanocomposites. Synthetic Metals, 230, 39-50.
[46] Hamra, A. A. B., Lim, H. N., Hafiz, S. M., Kamaruzaman, S., Rashid, S. A., Yunus, R., ... & Huang, N. M. (2018). Performance stability of solid-state polypyrrole-reduced graphene oxide-modified carbon bundle fiber for supercapacitor application. Electrochimica Acta, 285, 9-15.
[47] Li, J., Cheng, X., Sun, J., Brand, C., Shashurin, A., Reeves, M., & Keidar, M. (2014). based ultracapacitors with carbon nanotubes-graphene composites. Journal of Applied Physics, 115(16), 164301.
[48] Hwang, J., Jang, J., Hong, K., Kim, K. N., Han, J. H., Shin, K., & Park, C. E. (2011). Poly (3-hexylthiophene) wrapped carbon nanotube/poly (dimethylsiloxane) composites for use in finger-sensing piezoresistive pressure sensors. Carbon, 49(1), 106-110.
[49] P.Pötschke, K.Kobashi, T; Villmow, T. Andres, M.C ; Paiva, J.A Covas,( 2011). Compos. Sci. Technol. 71 (12), 1451–1460.
[50] Yu, M., He, Q., Yu, D., Zhang, X., Ji, A., Zhang, H., ... & Dai, Z. (2012). Efficient active actuation to imitate locomotion of gecko's toes using an ionic polymer-metal composite actuator enhanced by carbon nanotubes. Applied Physics Letters, 101(16), 163701.
[51] S.K Yadav, I.J .; Kim, H.I .; Kim, J..; Kim, S.M HongC.M Koo, (2013). J. Mater. Chem. C 1 (35), 5463–5470..
[52] Kazaoui, S., Minami, N., Nalini, B., Kim, Y., & Hara, K. (2005). Near-infrared photoconductive and photovoltaic devices using single-wall carbon nanotubes in conductive polymer films. Journal of applied physics, 98(8), 084314.
[53] Mao, G., Saboungi, M. L., Price, D. L., Badyal, Y. S., & Fischer, H. E. (2001). Lithium environment in PEO-LiClO4 polymer electrolyte. EPL (Europhysics Letters), 54(3), 347.
[54] Kim, D., & Yun, K. S. (2013). Patterning of carbon nanotube films on PDMS using SU-8 microstructures. Microsystem technologies, 19(5), 743-748.
[55] Liu, G. (2002). Investigation of ductile fracture under tensile high rate loading (Doctoral dissertation, Carleton University).
[56] Kurdi, J., & Tremblay, A. Y. (2003). Improvement in polyetherimide gas separation membranes through the incorporation of nanostructured metal complexes. Polymer, 44(16), 4533-4540.
[57] Ren, J., Zhou, J., & Deng, M. (2010). Morphology transition of asymmetric polyetherimide flat sheet membranes with different thickness by wet phase-inversion process. Separation and purification technology, 74(1), 119-129.
[58] Kim, H. S., Waqued, S. C., Nodurft, D. T., Devarenne, T. P., Yakovlev, V. V., & Han, A. (2017). Raman spectroscopy compatible PDMS droplet microfluidic culture and analysis platform towards on-chip lipidomics. Analyst, 142(7), 1054-1060.
[59] Pan, Y., Wang, L., Su, X., Gao, D., & Cheng, P. (2021). Nanolasers Incorporating Co x Ga0. 6–x ZnSe0. 4 Nanoparticle Arrays with Wavelength Tunability at Room Temperature. ACS Applied Materials & Interfaces, 13(5), 6975-6986.
[60] Palmer, M. V., Thacker, T. C., Waters, W., Gortázar, C., & Corner, L. A. (2012). Veterinary medicine international, 2012.