Shape memory nanocomposite

Pandini, S., Passera, S., Messori, M., Pademi, K., Toselli, M, Gianoncelh, A., Bontempi, E, and Ricco, T. (2012) Two-way reversible shape memory behaviour of crosslinked poly(8-caprolactone). Polymer, 53 (9), 1915-1924. Alvarado-Tenorio, B., Romo-Uribe, A., and Mather, P.T. (2011) Microstructure and phase behavior of POSS/PCL shape memory nanocomposites. Macromolecules, 44 (14), 5682-5692. 

Ishida, K., Hortensius, R., Luo, X., and Mather, P.T. (2012) Soft bacterial polyester-based shape memory nanocomposites featuring reconfigurable nanostructure. J. Polym. ScL, Part B Polym Phys., 50 (6), 387-393. 

Xu B, Huang WM, Pei YT, Chen ZG, Kraft A, Reuben R, De Hosson JTM, Fu YQ (2009) Mechanical properties of attapulgite clay reinforced polyurethane shape-memory nanocomposites. Eur Polym J 45 1904-1911... 

Lu H, Huang WM, Leng J (2014) Functionally graded and seb-asstanbled carbon nanofiber and boron nitride in nanopaper fm electrical actuation of shape memory nanocomposites. Compos B Eng 62 1-4... 

Alvarado-Tenorio B, Romo-Uribe A, Mather PT (2012) Stress-induced bimodal (ndering in POSS/PCL biodegradable shape memory nanocomposites. MRS Proc 1450 3-23. doi 10. 1557/opl.2012.1327... 

Raja M, Shanmugharaj AM, Ryu SH, Subha J (2011) Influence of metal nanoparticle decorated CNTs on polyurethane based electro active shape memory nanocomposite actuators. Mater Chem Phys 129(3) 925-931... 

H. Luo, J. Hu, and Y. Zhu, Polymeric Shape Memory Nanocomposites with Heterogeneous Twin Switches. Macromol. Chem. Phys. 212,1981-1986 (2011). 

Polycatenanes, 17 60 Poly(y-caprolactone)dimethylacry, in shape-memory polymers, 22 357 Poly(y-caprolactone)/OMLS nanocomposite, 20 311 Poly(y-caprolactone) switching segment, in shape-memory polymers, 22 362-363 Polychlorinated biphenyls (PCBs),... 

Better dispersion of MWNTs in the polymer matrix caused by the formation of the chemical bonds leads to uniform stress distribution and enhanced shape memory (23). Jana et al. prepared nanocomposites of PU and MWNTs via in-situ polymerization and conventional method (105). PU nanocomposites obtained via an in-situ method with PCL-g-MWNTs showed better shape recovery, compared to conventional nanocomposites. 

K. Gall, M.L. Dunn, Y. Liu, G. Stefanic, and D. Balzar, Internal stress storage in shape memory polymer nanocomposites, Appl. Phys. Lett, 85, 290-292 (2004). 

Gunes, I.S. and Jana, S.C. (2008) Shape memory polymers and their nanocomposites a review of science and technology of new multifunctional materials. Journal of Nanoscience and Nanotechnology, 8, 1616-1637. 

Abstract This chapter describes vegetable oil-based polymer nanocomposites. It deals with the importance, comparison with conventional composites, classification, materials and methods, characterisation, properties and applications of vegetable oil-based polymer nanocomposites. The chapter also includes a short review of polymer nanocomposites of polyester, polyurethanes and epoxies based on different vegetable oils and nanomaterials. The chapter shows that the formation of suitable vegetable oil-based polymer nanocomposite can be considered to be a means of enhancing many of the desirable properties of such polymers or of obtaining materials with an intrinsically new set of properties which will extend their utility in a variety of advanced applications. Vegetable oil-based shape memory hyperbranched polyurethane nanocomposites can be sited as an exampie of such advanced products. 

In addition to the above, many other properties, including optical, magnetic, electrical, catalytic, shape memory and adhesion are improved, according to the requirements and suitability of such nanocomposites and are discussed under the appropriate headings. 

Images of different states of shape memory MWNT/ hyperbranched polyurethane nanocomposites. 

Conductive polymer nanocomposites may also be used in different electrical applications such as the electrodes of batteries or display devices. Linseed oil-based poly(urethane amide)/nanostuctured poly(l-naphthylamine) nanocomposites can be used as antistatic and anticorrosive protective coating materials. Castor oil modified polyurethane/ nanohydroxyapatite nanocomposites have the potential for use in biomedical implants and tissue engineering. Mesua ferrea and sunflower seed oil-based HBPU/silver nanocomposites have been found suitable for use as antibacterial catheters, although more thorough work remains to be done in this field. ° Sunflower oil modified HBPU/silver nanocomposites also have considerable potential as heterogeneous catalysts for the reduction of nitro-compounds to amino compounds. Castor oil-based polyurethane/ epoxy/clay nanocomposites can be used as lubricants to reduce friction and wear. HBPU of castor oil and MWCNT nanocomposites possesses good shape memory properties and therefore could be used in smart materials. ... 

Phys. Chem. C, 113 (41), 17630-17635. Xiao, Y, Zhou, S., Wang, L., and Gong, T. (2010) Electro-active shape memory properties of poly(8-caprolactone)/functionalized multiwalled carbon nanotube nanocomposite. 

Kumar, U.N., Kratz, K., Behl, M., and Lendlein, A. (2012) Shape-memory properties of magnetically active triple-shape nanocomposites based on a grafted polymer network with two crystallizable switching segments. eXPRESS Polym. 

Cao, F. and Jana, S.C. (2007) Nanoclay-tethered shape memory polyurethane nanocomposites. Polymer, 48 (13), 3790-3800. 

A. M. (2013) Thermal, mechanical and electroactive shape memory properties of polyurethane (PU)/poly(lactic acid)(PLA)/CNT nanocomposites. Eur. Polyrtu /., 49 (11), 3492-3500. 

Effect of thermal expansion on shape memory behavior of polyurethane and its nanocomposites. J. Polym. Sd. Part B ... 

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