High-efficiency metalenses for zone-plate-array lithography

Henry I. Smith, Mark Mondol, Feng Zhang, Timothy Savas, Michael Walsh
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Abstract

To date, zone-plate-array lithography has employed an array of binary pi-phase zone plates, each 135 μm in diameter, operating at 405 nm wavelength, in conjunction with a spatial-light modulator and a moving stage, to expose large-area patterns in photoresist without a mask. Although the low focal efficiency (<34%) and high background (>66%) of such zone plates can be mitigated via proximity-effect correction, increased focal efficiency would enable higher quality patterning. To that end, we have designed flat, diffractive-optical “metalenses.” Each is first divided into Fresnel zones, across which the effective index-of-refraction is modulated by forming appropriate pillars or holes such that diffracted beams interfere constructively at the focal spot, located 100 μm in front of the lens plane. The diffraction efficiency of each zone is simulated using rigorous-coupled-wave analysis. A genetic algorithm is then used to determine if higher efficiency can be achieved by repositioning of the pillars or modifying their widths. MEEP software is used to predict focal efficiency of the completed metalens design. Scanning-electron-beam lithography was used to fabricate effective-index-modulated metalenses in CSAR-62 e-beam resist. In some cases, the focal properties and efficiencies of such structures were measured, yielding focal efficiencies up to 54%. In other cases, the e-beam-written pattern was transferred into a spin-on hard mask and then into an organic dielectric of 1.9 index of refraction using reactive ion etching. Focal efficiencies up to 69% are predicted for such structures, a significant improvement over the binary pi-phase zone plates used previously.
用于区板阵列光刻的高效超透镜
迄今为止,带板阵列光刻技术已经采用了一组双相带板,每个直径为135 μm,工作波长为405 nm,与空间光调制器和移动平台相结合,可以在没有掩膜的情况下暴露光刻胶中的大面积图案。虽然这种带片的低焦效率(<34%)和高背景(>66%)可以通过邻近效应校正来减轻,但提高焦效率将实现更高质量的图案。为此,我们设计了平面的衍射光学“超透镜”。每个透镜首先被划分为菲涅耳区,通过形成适当的柱或孔来调制有效折射率,从而使衍射光束在位于透镜平面前方100 μm的焦点处产生建设性干涉。采用严格耦合波分析模拟了各区域的衍射效率。然后使用遗传算法来确定是否可以通过重新定位支柱或修改其宽度来实现更高的效率。利用MEEP软件对超构透镜设计完成后的聚焦效率进行了预测。采用扫描电子束光刻技术在CSAR-62电子束抗蚀剂中制备了有效折射率调制的超透镜。在某些情况下,测量了这种结构的焦点特性和效率,产生的焦点效率高达54%。在其他情况下,电子束写入图案被转移到自旋硬掩模中,然后使用反应离子蚀刻进入1.9折射率的有机电介质中。预计这种结构的聚焦效率可达69%,与之前使用的二元pi相带片相比,这是一个显著的改进。
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