期刊
ACS NANO
卷 8, 期 11, 页码 11061-11070出版社
AMER CHEMICAL SOC
DOI: 10.1021/nn504214b
关键词
nanophotonics; metasurfaces; nanoantennas; plasmonics; nanofabrication; nanosphere lithography; colloidal lithography; shadow-sphere lithography
类别
资金
- Office of Naval Research [N00014-10-1-0942]
- Marie Curie project SAM-TunEGaln [IOF-2012-328412]
- National Science Foundation (NSF) [DMR-0820484, DMR-1262895]
- NSF [ECS-0335765]
- Direct For Mathematical & Physical Scien [1262895] Funding Source: National Science Foundation
Optical metasurfaces-patterned arrays of plasmonic nanoantennas that enable the precise manipulation of lightmatter interactions-are emerging as critical components in many nanophotonic materials, including planar metamaterials, chemical and biological sensors, and photovoltaics. The development of these materials has been slowed by the difficulty of efficiently fabricating patterns with the required combinations of intricate nanoscale structure, high areal density, and/or heterogeneous composition. One convenient strategy that enables parallel fabrication of periodic nanopatterns uses self-assembled colloidal monolayers as shadow masks; this method has, however, not been extended beyond a small set of simple patterns and, thus, has remained incompatible with the broad design requirements of metasurfaces. This paper demonstrates a technique-shadow-sphere lithography (SSL)-that uses sequential deposition from multiple angles through plasma-etched microspheres to expand the variety and complexity of structures accessible by colloidal masks. SSL harnesses the entire, relatively unexplored, space of shadow-derived shapes and-with custom software to guide multiangled deposition-contains sufficient degrees of freedom to (i) design and fabricate a wide variety of metasurfaces that incorporate complex structures with small feature sizes and multiple materials and (ii) generate, in parallel, thousands of variations of structures for high-throughput screening of new patterns that may yield unexpected optical spectra. This generalized approach to engineering shadows of spheres provides a new strategy for efficient prototyping and discovery of periodic metasurfaces.
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