Mechanical Deformation–Assisted Fabrication of Plasmonic Nanobowties with Broken Symmetry and Tunable Gaps

Liu, Yue Feng; Zhang, Runyu

doi:10.1002/ppsc.201900463

Cited by 5 publications

(4 citation statements)

References 36 publications

(70 reference statements)

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“…using nanosphere lithography to fabricate triangles on a pre‐stretched PDMS substrate. [ 104 ] A monolayer of polystyrene (PS) beads was deposited on pre‐stretched PDMS (0%, 10%, 20%, 30%), and 5 nm chromium and 50 nm gold were deposited. After removing the PS bead mask, the PDMS was relaxed, which resulted in the adjacent triangles moving closer together, forming bow tie antennas from two triangles with gaps down to 20 nm.…”

Section: Individual Mechanically Tunable Nanogap Antennas On Flexible Substratesmentioning

confidence: 99%

Mechanically Tunable Nanogap Antennas: Single‐Structure Effects and Multi‐Structure Applications

Laible

Horneber

Fleischer

2021

Advanced Optical Materials

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By mechanically changing the width of a nanometer gap between two optical antennas, the coupling condition for the antennas can be seamlessly modified. This leads to a shift in the antenna's localized surface plasmon resonance wavelength, and a modification of the intensity in the antenna hotspot, which can reach extraordinarily high values for nanometer gaps. Such systems have in recent years been realized, for example, by using flexible polymers as substrates that are mechanically stretched or bent, or by combining break junctions with plasmonic antennas. Applications can be found, amongst others, in plasmonic strain sensing via color shift sensors, or tunable surface‐enhanced Raman spectroscopy platforms. In this article an overview is given over recent work on mechanically tunable gap antennas, with a specific focus on studies at the single‐nanostructure level. Different techniques used for mechanical tuning, optical read‐out signals that are influenced by the gap width, and potential applications of the resulting structures are presented. Plasmonic break junctions offer a new perspective that allows for added functionalities. The mechanical activation is discussed within the context of single nanoantenna gap tuning by using alternative stimuli.

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Section: Individual Mechanically Tunable Nanogap Antennas On Flexible Substratesmentioning

confidence: 99%

Mechanically Tunable Nanogap Antennas: Single‐Structure Effects and Multi‐Structure Applications

Laible

Horneber

Fleischer

2021

Advanced Optical Materials

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“…Mechanical deformation can directly reform the lattice periodicity of the meta-atoms, and is hence deemed as an efficient approach for active metasurfaces for spectrum tuning [32] , structural colors [33] , varifocusing [34] , dynamic holography [35] , and so on. Several metasurfaces fabricated on soft substrates exhibit spectral tuning upon externally applied strain through mechanical stretching [33,36,37] . To exclude the cumbrous physical contact for obtaining the deformation and to miniaturize the system size for further optoelectronic integration, active metasurfaces possessing mechanical deformability that can be controlled with remote stimuli would be strongly desired.…”

Section: Introductionmentioning

confidence: 99%

“…Several metasurfaces fabricated on soft substrates exhibit spectral tuning upon externally applied strain through mechanical stretching. 33,36,37 To exclude the cumbrous physical contact for obtaining the deformation and to miniaturize the system size for further optoelectronic integration, active metasurfaces possessing mechanical deformability that can be controlled with remote stimuli would be strongly desired.…”

Section: Introductionmentioning

confidence: 99%

Photoelastic plasmonic metasurfaces with ultra-large near infrared spectral tuning

et al. 2022

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“…Their plasmonic coupling increases, thus enhancing the local electromagnetic field [31]. Strain sensitive experiments with bowtie nanoantennae on PDMS allowed for further LSP investigations [26,32,33].…”

Section: Introductionmentioning

confidence: 99%

Hexagonal arrays of plasmonic gold nanopyramids on flexible substrates for surface-enhanced Raman scattering

et al. 2021

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Surface-enhanced Raman scattering (SERS) with pyramidal nanostructures increases the signal of Raman active analytes, since hotspots form at the edges and tip of a nano-pyramid under illumination. 2D hexagonal arrays of pyramidal nanostructures with a quadratic base are fabricated through cost-effective nano-sphere lithography and transferred onto elastomeric polydimethylsiloxane (PDMS). By making use of the {111} crystal plane of a silicon (100) wafer, an inverted pyramidal array is etched, which serves as the complementary negative for the gold nanostructures. Either a continuous gold thin-film with protruding pyramids or separate isolated nano-pyramids are produced. Three main fabrication strategies are presented, in which a linker molecule between the PDMS and the gold is mandatory to increase the weak Au-PDMS adhesion. 3-Mercaptopropyltriethoxysilane (MPTS) is able to bind to both PDMS and to the gold structures, thus strongly increasing stability under mechanical strain. The SERS enhancement is verified by Raman mapping of 4-mercaptobenzoic acid (4-MBA) molecules. Fabrication on a flexible substrate paves the way for future applications on curved surfaces or insitu tunable resonances.

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Mechanical Deformation–Assisted Fabrication of Plasmonic Nanobowties with Broken Symmetry and Tunable Gaps

Cited by 5 publications

References 36 publications

Mechanically Tunable Nanogap Antennas: Single‐Structure Effects and Multi‐Structure Applications

Mechanically Tunable Nanogap Antennas: Single‐Structure Effects and Multi‐Structure Applications

Photoelastic plasmonic metasurfaces with ultra-large near infrared spectral tuning

Hexagonal arrays of plasmonic gold nanopyramids on flexible substrates for surface-enhanced Raman scattering

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