Switchable Plasmonics: Switchable Plasmonic Nanocomposites (Advanced Optical Materials 1/2019)
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In article number 1801101, Mady Elbahri and Shahin Homaeigohar provide a review that, starting from the ancient switchable plasmonic nanocomposites, up to the present of reversible plasmonic reconfiguration with order–disorder switching, ends up with the new class of switchable plasmonic molecules as a future outlook.Keywords:
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Nanocomposites of polyurethane were prepared from inorganic nano particles, (MMT), silica, , and surface modified MMT and their properties were investigated. It was shown that the molecular weight and polydispenity of nanocomposites of polyurethane were 20000 to 28000 and 1.0 to 2.0, respectively. d-Spacing for nanocomposites of MMT were increased than that of pure MMT. Initial degradation temperature of nanocomposites were 250 to . And also, the range of weight loss for nanocomposites were decreased and the end of thermal degradation was observed at higher temperatures about . The elongation at break for filled nanocomposites were the highest among the nanocomposites used in this study. studied. It was found that the tensile strength increased with increasing the filler contents while the silica nanocomposite exhibited the lowest increase and the nanocomposite the highest.
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基于 Cu 的 thermosensitive nanocomposites 被高精力球 milling 做。基于 Cu 的 thermosensitive nanocomposites 的微观结构和性质被传播电子显微镜学(TEM ) 和 themosensitivity 测试学习。milling 时间在微观结构的效果和基于 Cu 的 nanocomposite 材料的 thermosensitivity 被研究。基于 Cu 的 nanocomposite 能被高精力球 milling 做的 Theresults 表演。作为他们, illing 时间增加,在 nanocomposite 的铜粒子尺寸减少,然后, nanocomposite 的 thethermoexpansivity 增加。当 milling 时间直到 100 h 时, nanocomposite 具有最好的 thermoexpansivity。在 35-45 deg C, nanocomposite 显示出好 thermosensitivity。
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Abstract The sections in this article are Introduction Requirements for Successful Tissue Engineering Composites and Nanocomposites Composites Nanocomposites Hybrids Biological Nanocomposites Bone Biological Nanocomposites as Scaffolds Organic–Organic Nanocomposites Inorganic–Inorganic Nanocomposites Organic–Inorganic Composites Mineralized Collagen: Nanocomposites that Mimic the ECM of Bone Silica‐Based Nanocomposites for Tissue Engineering Organic–Inorganic Nanocomposites Containing Fibers Nanocomposites Containing Carbon Nanotubes ( CNTs ) Summary and Outlook
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