Templating Colloidal Crystal Growth Using Chirped Surface Relief Gratings

Mahmood, Russell; Mettry, Andrew; Hillier, Andrew C.

doi:10.1021/acs.langmuir.8b00773

Cited by 3 publications

(1 citation statement)

References 41 publications

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“…Photonic bandgap (PBG) materials are structured objects with periodic spatial variations in refractive index possessing unit cell sizes comparable to the wavelength of light . PBG materials can manipulate light owing to the overlap between their structural length scales and the wavelength of visible light. − The target wavelength of a PBG material is determined by the intrinsic properties of the material as well as its geometry. By adjusting the periodicity and lattice structures of a PBG, the target wavelength and polarization direction can be controlled.…”

Section: Introductionmentioning

confidence: 99%

Creating Two-Dimensional Quasicrystal, Supercell, and Moiré Lattices with Laser Interference Lithography: Implications for Photonic Bandgap Materials

Mahmood

Hillier

2021

ACS Appl. Nano Mater.

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We extend the patterning capability of laser interference lithography (LIL) to fabricate complex two-dimensional quasicrystal lattices, superlattices, and Moiré lattices. Traditional interference lithography is typically used to create single-pitch linear gratings or simple square or hexagonal patterns. In this work, we demonstrate how using multiple exposures at various defined orientations and with different interference pitch values results in a cumulative surface pattern that encompasses a diverse group of complex lattice structures. We demonstrate the fabrication of quasicrystal lattices of symmetry order ranging from 2-fold to 22-fold by repeated exposure of a one-dimensional interference pattern over multiple fixed sample rotation angles. More complex superlattice structures are prepared by overlapping two-dimensional lattices at controlled offset angles. Overlapping interference patterns with different pitch values and at different offsets are used to create various sophisticated incommensurate Moiré lattices. The increasing complexity of these surfaces is determined using a numerical algorithm to predict their structure. The structure and optical diffraction of these lattices were measured and compared to model results. This work extends the capabilities of LIL to provide access to a wide variety of complex nanostructures with tunable periodicity and controllable symmetry. We anticipate that these structures will prove useful in the fabrication of surfaces and devices based upon periodic two-dimensional nanostructures, including photonic bandgap materials with tunable band gaps, as platforms for plasmonic devices with complex engineered structures, as novel diffractive optical elements, and as templates for controlling the self-assembly and crystallization of colloidal crystals.

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Section: Introductionmentioning

confidence: 99%

Creating Two-Dimensional Quasicrystal, Supercell, and Moiré Lattices with Laser Interference Lithography: Implications for Photonic Bandgap Materials

Mahmood

Hillier

2021

ACS Appl. Nano Mater.

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“Tunable colloids”: Experimental complex for studying generic phenomena in classical condensed matter

Yakovlev

Ovcharov

Yurchenko

2018

J. Phys.: Conf. Ser.

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The Prospects of Colloidal Lithography Towards Low-Cost and Scalable Sensors

Purwidyantri

Prabowo

2022

IEEE Nanotechnology Mag.

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Nanosphere lithography (NSL), a colloidal-based nanopatterning technique, has demonstrated versatility for bottom-up and top-down nanofabrication approaches with a simple procedure that can be performed in a standard chemical laboratory. This technique offers versatility for large-area nanopatterning with a low-cost process. Nanopatterned arrays have shown outstanding features in enhancing sensor performance due to their ability to create effective nanoscale physical and chemical changes, high molecular entrapment with the roughened substrate, and means of downscaling toward scalable sensors manufacturing. All these prominent properties have made NSL a promising candidate for scalable biosensors production as its performance is also highly comparable with the pre-existing lithography techniques that mostly require high-cost infrastructure. This mini-review discusses in detail the advantages of colloidal lithography over other lithography techniques from the resolution and scalability of manufacturing. It is emphasized that the cost-competitive NSL technology may be applicable for a broad range of end-users, from high-profit margins, such as communication, technology, and health sectors, to the low-profit margins, such as in food industries. The combinational strategies in NSL are presented, including polystyrene nanotemplating of the substrate, feasible integration with metallic film deposition technologies, and potential application in various sensing platforms.

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Templating Colloidal Crystal Growth Using Chirped Surface Relief Gratings

Cited by 3 publications

References 41 publications

Creating Two-Dimensional Quasicrystal, Supercell, and Moiré Lattices with Laser Interference Lithography: Implications for Photonic Bandgap Materials

Creating Two-Dimensional Quasicrystal, Supercell, and Moiré Lattices with Laser Interference Lithography: Implications for Photonic Bandgap Materials

“Tunable colloids”: Experimental complex for studying generic phenomena in classical condensed matter

The Prospects of Colloidal Lithography Towards Low-Cost and Scalable Sensors

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