Metallic nanorods array for magnified subwavelength imaging (Presentation Recording)

Y. Ohashi, Bikas Ranjan, Y. Saito, P. Verma
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Abstract

Earlier, our group proposed a lens made of metallic nanorods, stacked in 3D arrays tapered in a conical shape. This nanolens could theoretically realize super-resolution color imaging in the visible range. The image could be magnified and transferred through metallic nanorods array. Lithography or self-assembly are common ways to fabricate such nanostructured devices. However, to precisely arrange nanorods is challenging due to the limitations to scale down components, and to increase accuracy of assembling particles in large area. Here we experimentally demonstrated 2D nanolens with long chains of metallic nanorods placed at tapered angles in a fan-like shape to magnify images. In the fabrication, we chemically synthesized gold nanorods coated with CTAB surfactant to ensure a 10 nm gap between the rods for the resonance control of nanolens. And we prepared trenches patterned by FIB lithography on a PMMA coated glass substrate. The different hydrophobicity of PMMA and CTAB coats enabled to optimize capillary force in gold nanorod solution and selectively assemble nanorods into hydrophilic trenches. Finally, we obtained 2D nanolens after lift-off of the PMMA layer. We numerically estimated the resonance property of nanorods chain and found a broad peak in the visible range located at a wavelength of 727 nm. The broadness of this peak (~178 nm) confirms that a broad range of wavelength can be resonant with this structure. This phenomenon was also confirmed experimentally by optical measurements. These results show that the combination of lithography and self-assembly has the potential to realize plasmonic nanolens.
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用于放大亚波长成像的金属纳米棒阵列(演示记录)
早些时候,我们的团队提出了一种由金属纳米棒制成的透镜,以锥形锥形的3D阵列堆叠。该纳米透镜理论上可以实现可见光范围内的超分辨率彩色成像。图像可以通过金属纳米棒阵列进行放大和传输。光刻或自组装是制造这种纳米结构器件的常用方法。然而,纳米棒的精确排列是一个挑战,因为限制了组件的缩小,并提高了大面积组装颗粒的精度。在这里,我们实验展示了二维纳米透镜,金属纳米棒的长链以锥形角度呈扇形放置,以放大图像。在制作过程中,我们化学合成了涂有CTAB表面活性剂的金纳米棒,以确保棒之间有10 nm的间隙,以用于纳米透镜的共振控制。并在PMMA镀膜玻璃基板上制备了FIB光刻沟槽。PMMA和CTAB涂层的不同疏水性可以优化金纳米棒溶液中的毛细力,并选择性地将纳米棒组装成亲水沟槽。最后,我们获得了PMMA层剥离后的二维纳米透镜。我们对纳米棒链的共振特性进行了数值估计,发现在可见光范围内727 nm处有一个宽峰。该峰的宽度(~178 nm)证实了该结构可以在很宽的波长范围内共振。这一现象也被光学测量实验证实。这些结果表明,光刻和自组装相结合具有实现等离子体纳米透镜的潜力。
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