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Nanofabrication of High-Resolution Periodic Structures with a Gap Size Below 100 nm by Two-Photon Polymerization

机译：间隙尺寸小于100 nm的高分辨周期结构的双光子聚合纳米加工。

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摘要

In this paper, approaches for the realization of high-resolution periodic structures with gap sizes at sub-100 nm scale by two-photon polymerization (2PP) are presented. The impact of laser intensity on the feature sizes and surface quality is investigated. The influence of different photosensitive materials on the structure formation is compared. Based on the elliptical geometry character of the voxel, the authors present an idea to realize high-resolution structures with feature sizes less than 100 nm by controlling the laser focus position with respect to the glass substrate. This investigation covers structures fabricated respectively in the plane along and perpendicular to the major axis of voxel. The authors also provide a useful approach to manage the fabrication of proposed periodic structure with a periodic distance of 200 nm and a gap size of 65 nm.

机译：本文提出了通过两光子聚合（2PP）实现间隙尺寸在100 nm以下的高分辨率周期性结构的方法。研究了激光强度对特征尺寸和表面质量的影响。比较了不同光敏材料对结构形成的影响。基于体素的椭圆几何特征，作者提出了一种想法，即通过控制相对于玻璃基板的激光聚焦位置来实现特征尺寸小于100 nm的高分辨率结构。这项研究涵盖了分别在沿着和垂直于体素主轴的平面中制造的结构。作者还提供了一种有用的方法来管理建议的周期结构的制造，该周期结构的周期距离为200 nm，间隙尺寸为65 nm。

著录项

期刊名称 Nanoscale Research Letters
作者
Lei Zheng; Kestutis Kurselis; Ayman El-Tamer; Ulf Hinze; Carsten Reinhardt; Ludger Overmeyer; Boris Chichkov;
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作者单位

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年(卷),期 2019(14),-1
年度 2019
页码 134
总页数 9
原文格式 PDF
正文语种
中图分类生化遗传学;生化药理学;
关键词
Nanofabrication Two-photon polymerization Sub-100 nm Periodic structures;

机译：纳米制造;双光子聚合;低于100 nm;周期性结构;

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专利

1. Nanofabrication of High-Resolution Periodic Structures with a Gap Size Below 100 nm by Two-Photon Polymerization [J] . Lei Zheng, Kestutis Kurselis, Ayman El-Tamer, Nanoscale Research Letters . 2019,第1期

机译：间隙尺寸小于100 nm的高分辨率周期性结构的双光子聚合纳米加工
2. Materials and technologies for fabrication of three-dimensional microstructures with sub-100nm feature sizes by two-photon polymerization [J] . Frank BurmeisterSo¨nke Steenhusenb) and Ruth HoubertzUwe D. Zeitner Stefan Nolte and Andreas Tu¨nnermann Journal of Laser Applications . 2012,第4期

机译：通过双光子聚合制备特征尺寸小于100nm的三维微观结构的材料和技术
3. Development of functional sub-100 nm structures with 3D two-photon polymerization technique and optical methods for characterization [J] . V. Ferreras PazM. EmonsK. Obataa) and A. OvsianikovS. Peterha¨nsel and K. FrennerC. Reinhardt and B. ChichkovU. MorgnerW. Osten Journal of Laser Applications . 2012,第4期

机译：利用3D双光子聚合技术开发光学亚100 nm结构并进行表征的光学方法
4. Two-photon polymerization as a high-resolution tool to control surface structure of polymeric biomaterials at micro- and nanoscale [C] . David Barata, Paulo Dias, Clemens A. van Blitterswijk, European conference on biomaterials . 2014

机译：双光子聚合作为高分辨率工具，可在微米和纳米级控制聚合物生物材料的表面结构
5. Periodic polymer photonic bandgap structures for on-chip optical cavities. [D] . Liu, Tao. 2008

机译：用于片上光腔的周期性聚合物光子带隙结构。
6. Scaling-Up Techniques for the Nanofabrication of Cell Culture Substrates via Two-Photon Polymerization for Industrial-Scale Expansion of Stem Cells [O] . Davide Ricci, Michele M. Nava, Tommaso Zandrini, 2017

机译：通过双光子聚合技术对干细胞进行工业规模扩展的纳米制造细胞培养基质的放大技术。
7. Nanofabrication of High-Resolution Periodic Structures with a Gap Size Below 100 nm by Two-Photon Polymerization [O] . Lei Zheng, Kestutis Kurselis, Ayman El-Tamer, 2019

机译：通过双光子聚合纳米间隙尺寸的高分辨率周期结构的高分辨率周期结构
8. Fabrication of Sub-100 nm Linewidth Periodic Structures for Study of Quantum Effects from Interference and Confinement in Si Inversion Layers [R] . Warren, A. C., Plotnik, I., Anderson, E. H., 1986

机译：用于研究si反转层中干涉和限制的量子效应的亚100nm线宽周期结构的制作

Nanofabrication of High-Resolution Periodic Structures with a Gap Size Below 100 nm by Two-Photon Polymerization

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