ICFO-Institut de Ciencies Fotoniques, The Barcelona Institute of Science and Technology , 08860 Castelldefels (Barcelona), Spain.
State Key Laboratory of Modern Optical Instrumentation, Zhejiang University , Hangzhou 310027, China.
ACS Nano. 2017 Aug 22;11(8):7915-7924. doi: 10.1021/acsnano.7b02426. Epub 2017 Jul 25.
Metallodielectric multishell nanoparticles are capable of hosting collective plasmon oscillations distributed among different metallic layers, which result in large near-field enhancement at specific regions of the structure, where light absorption is maximized. We exploit this capability of multishell nanoparticles, combined with thermal boundary resistances and spatial tailoring of the optical near fields, to design plasmonic nano-ovens capable of achieving high temperatures at the core region using moderate illumination intensities. We find a large optical intensity enhancement of ∼10 over a relatively broad core region with a simple design consisting of three metal layers. This provides an unusual thermal environment, which together with the high pressures of ∼10 atm produced by concatenated curved layers holds great potential for exploring physical and chemical processes under extreme optical/thermal/pressure conditions in confined nanoscale spaces, while the outer surface of the nano-oven is close to ambient conditions.
金属-电介质多壳纳米粒子能够承载分布在不同金属层中的集体等离激元振荡,这导致在结构的特定区域产生大的近场增强,其中光吸收被最大化。我们利用多壳纳米粒子的这种能力,结合热边界电阻和光学近场的空间调整,设计出等离子体纳米烤箱,能够在使用中等光强的情况下,使核心区域达到高温。我们发现,由三层金属组成的简单设计在相对较宽的核心区域内实现了约 10 的大光学强度增强。这提供了一个不寻常的热环境,再加上由串联弯曲层产生的约 10 大气压的高压,为在受限的纳米空间内探索极端光学/热/压条件下的物理和化学过程提供了巨大的潜力,而纳米烤箱的外表面接近环境条件。
