Large‐Area Fabrication of Periodic Arrays of Nanoholes in Metal Films and Their Application in Biosensing and Plasmonic‐Enhanced Photovoltaics

Menezes, J. W.; Ferreira, Josiel; Santos, Jacqueline Ferreira Leite; Cescato, Lucila; Brolo, Alexandre G.

doi:10.1002/adfm.201001262

Cited by 130 publications

(108 citation statements)

References 45 publications

(57 reference statements)

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“…The diameter and periodicity of the hole and the thickness of the metal fi lm can be well controlled to achieve optimized plasmonic resonance. A photocurrent enhancement has been demonstrated in polymer solar cells [127] .…”

Section: Advanced Plasmonic Technologies For Solar Cell Applicationsmentioning

confidence: 99%

Nanoplasmonics: a frontier of photovoltaic solar cells

Ouyang

Jia

et al. 2012

Nanophotonics

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Nanoplasmonics recently has emerged as a new frontier of photovoltaic research. Noble metal nanostructures that can concentrate and guide light have demonstrated great capability for dramatically improving the energy conversion efficiency of both laboratory and industrial solar cells, providing an innovative pathway potentially transforming the solar industry. However, to make the nanoplasmonic technology fully appreciated by the solar industry, key challenges need to be addressed; including the detrimental absorption of metals, broadband light trapping mechanisms, cost of plasmonic nanomaterials, simple and inexpensive fabrication and integration methods of the plasmonic nanostructures, which are scalable for full size manufacture. This article reviews the recent progress of plasmonic solar cells including the fundamental mechanisms, material fabrication, theoretical modelling and emerging directions with a distinct emphasis on solutions tackling the above-mentioned challenges for industrial relevant applications.

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Section: Advanced Plasmonic Technologies For Solar Cell Applicationsmentioning

confidence: 99%

Nanoplasmonics: a frontier of photovoltaic solar cells

Ouyang

Jia

et al. 2012

Nanophotonics

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“…It is already well established that in such circumstances the plasmon tunnels through the aperture and decays to radiant photons upon penetrating the metal film. [19][20][21][22][23][24] By varying the size, shape, thickness and periodicity of the array, it is known that the permitted plasmon coupling frequency can be tuned, dictating the color of the transmitted light. 15,17,25,26 Typically, plasmonic cavity-aperture filters are comprised of circular nano-holes tuned to operate efficiently at a single wavelength.…”

mentioning

confidence: 99%

Dual Color Plasmonic Pixels Create a Polarization Controlled Nano Color Palette

2016

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Color filters based upon nano-structured metals have garnered significant interest in recent years, having been positioned as alternatives to the organic dye-based filters which provide color selectivity in image sensors, as non-fading 'printing' technologies for producing images with nanometer pixel resolution, and as ultra-high-resolution, small foot-print optical storage and encoding solutions. Here, we demonstrate a plasmonic filter set with polarizationswitchable color properties, based upon arrays of asymmetric cross-shaped nano-apertures in an aluminum thin-film. Acting as individual color-emitting nano-pixels, the plasmonic cavityapertures have dual-color selectivity, transmitting one of two visible colors, controlled by the polarization of the white light incident on the rear of the pixel and tuned by varying the critical dimensions of the geometry and periodicity of the array. This structural approach to switchable optical filtering enables a single nano-aperture to encode two information states within the same physical nano-aperture; an attribute we use here to create micro image displays containing duality in their optical information states.

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“…13,29,30 The localized surface plasmon resonances (LSPR) of these metallic arrays are a function of material, size, shape, spacing and periodicity of the structures. The size and the spacing of the structures could be adjusted by fine tuning the exposure times and the exposure angle.…”

Section: Discussionmentioning

confidence: 99%

“…11,12 Most researchers using Lloyd's systems have focused on creating uniform patterns over large areas. 13,14 However, for some studies, especially the those in the early device development stage, where systematic variation of parameters is necessary, fabrication of a variety of multiple and/or gradually changing structures on a single substrate is the desired goal. A typical example is the study of the influence of surface topographies in a systematic fashion in the field of cell biology, where the objective is to examine how cells respond to lines, broken lines and dots or combinations of them on microscopic to nanoscopic scales.…”

Section: Introductionmentioning

confidence: 99%

Large area periodic, systematically changing, multishape nanostructures by laser interference lithography and cell response to these topographies

et al. 2013

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Hamilton, Douglas W.; and Mittler, Silvia, "Large area periodic, systematically changing, multishape nanostructures by laser interference lithography and cell response to these topographies" (2013 Abstract. The fabrication details to form large area systematically changing multishape nanoscale structures on a chip by laser interference lithography (LIL) are described. The feasibility of fabricating different geometries including dots, ellipses, holes, and elliptical holes in both x-and y-directions on a single substrate is shown by implementing a Lloyd's interferometer. The fabricated structures at different substrate positions with respect to exposure time, exposure angle and associated light intensity profile are analyzed. Experimental details related to the fabrication of symmetric and biaxial periodic nanostructures on photoresist, silicon surfaces, and ion milled glass substrates are presented. Primary rat calvarial osteoblasts were grown on ion-milled glass substrates with nanotopography with a periodicity of 1200 nm. Fluorescent microscopy revealed that cells formed adhesions sites coincident with the nanotopography after 24 h of growth on the substrates. The results suggest that laser LIL is an easy and inexpensive method to fabricate systematically changing nanostructures for cell adhesion studies. The effect of the different periodicities and transition structures can be studied on a single substrate to reduce the number of samples significantly.

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Large‐Area Fabrication of Periodic Arrays of Nanoholes in Metal Films and Their Application in Biosensing and Plasmonic‐Enhanced Photovoltaics

Cited by 130 publications

References 45 publications

Nanoplasmonics: a frontier of photovoltaic solar cells

Nanoplasmonics: a frontier of photovoltaic solar cells

Dual Color Plasmonic Pixels Create a Polarization Controlled Nano Color Palette

Large area periodic, systematically changing, multishape nanostructures by laser interference lithography and cell response to these topographies

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