Interference lithography: a powerful tool for fabricating periodic structures

Lu, Cheng; Lipson, R. H.

doi:10.1002/lpor.200810061

Cited by 268 publications

(186 citation statements)

References 86 publications

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“…substrate. With an appropriate lowcost lithography tool, e.g., displacement Talbot lithography 23 or laser interference lithography, 24 one could easily pattern and evaporate nanogap arrays over a full wafer, which was, however, not a part of this study.…”

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confidence: 99%

Fabrication of sub-10 nm gap arrays over large areas for plasmonic sensors

Siegfried

Ekinci

Solak³

et al. 2011

Applied Physics Letters

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We report a high-throughput method for the fabrication of metallic nanogap arrays with high-accuracy over large areas. This method, based on shadow evaporation and interference lithography, achieves sub-10 nm gap sizes with a high accuracy of 61.5 nm. Controlled fabrication is demonstrated over mm 2 areas and for periods of 250 nm. Experiments complemented with numerical simulations indicate that the formation of nanogaps is a robust, self-limiting process that can be applied to wafer-scale substrates. Surface-enhanced Raman scattering (SERS) experiments illustrate the potential for plasmonic sensing with an exceptionally low standard-deviation of the SERS signal below 3% and average enhancement factors exceeding 1 Â 10 6 . 1,2 This enhancement phenomenon relies on strongly confined electromagnetic fields generated by localized plasmons on metal nanostructures much smaller than the incident wavelength. 3,4 However, surface enhanced (SE) spectroscopic techniques are not yet routinely used at the industrial level. This is due to poor signal reproducibility, moderate average enhancement factors, and high costs. 5 To increase the signal enhancement, nanogap patterns are currently used: they produce extremely large electromagnetic fields for nano objects separated by a distance below 20 nm. 6 Local enhancement factors up to $10 9 have been reported with a one-dimensional (1D) nanogap pattern, 7 enabling single molecule detection. 8 The fabrication of nanogap arrays has been demonstrated with a variety of techniques. Electron-beam lithography (EBL) is used for direct writing 9 or patterning of shadow masks for angular evaporation. 10,11 With EBL, the pattern can be designed and realized with an exceptional degree of freedom. Due to proximity effects of the electron beam and limitations set by the photoresist liftoff, the resulting metal nanogap dimensions are limited to above roughly 10 nm and a metal layer thickness of below 30 nm. 9,12 The serial writing process of EBL makes this technique unfavorable for the fabrication of large area and low-cost sensors. Other lithography-based techniques have been used, including molecular rulers 13,14 or atomic layer deposition (ALD), 7 as effective methods to tune the nanogap size even below 2 nm. This, however, involves complicated multistep fabrication processes and produces local defects, which are found to cause fluctuations of the surface-enhanced Raman scattering (SERS) enhancement across the sensing area 7 or between different substrates.In this letter, we report the fabrication of homogeneous sub-10 nm gap arrays with high surface densities and over large areas. The fabrication scheme for our nanogap arrays consists of only two stages, lithography and metal layer deposition.In the first step, extreme ultraviolet interference lithography (EUV-IL) is used to provide a 1D line array on the substrate, which is typically float glass or silicon. Details of the EUV lithography, available at the Swiss Light Source, can be found elsewhere. 15 This technique provides high resolu...

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confidence: 99%

Fabrication of sub-10 nm gap arrays over large areas for plasmonic sensors

Siegfried

Ekinci

Solak³

et al. 2011

Applied Physics Letters

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“…Laser interference lithography (LIL) is used for decades to pattern surfaces with periodic structures ranging from micron to sub-micron scales [1][2][3][4][5][6][7][8][9]. This technique allows to write 1D, 2D, and even 3-dimensional periodic patterns into a photoresist by adjusting the intensity, geometry, polarization, and phase of the applied laser light [6][7][8].…”

Section: Introductionmentioning

confidence: 99%

“…This technique allows to write 1D, 2D, and even 3-dimensional periodic patterns into a photoresist by adjusting the intensity, geometry, polarization, and phase of the applied laser light [6][7][8]. Since the fabrication of nano-and microstructured surfaces is a parallel process, LIL is competitive to other high-resolution lithographic techniques.…”

Section: Introductionmentioning

confidence: 99%

“…Since the fabrication of nano-and microstructured surfaces is a parallel process, LIL is competitive to other high-resolution lithographic techniques. Consequently, it is used for various industrial applications including but not limited to the field of solar cells and LED [10,11], laser technology [12], integrated optical design [1], data storage [13], optical communications [5], biomedical applications [14] and IC industries [8].…”

Section: Introductionmentioning

confidence: 99%

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Fabrication of hierarchical photonic nanostructures inspired by Morpho butterflies utilizing laser interference lithography

Siddique

Hünig

Faisal

et al. 2015

Opt. Mater. Express

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Abstract:We introduce laser interference lithography (LIL) as a tool to fabricate hierarchical photonic nanostructures inspired by blue Morpho butterflies. For that, we utilize the interference pattern in vertical direction in addition to the conventional horizontal one. The vertical interference creates the lamellae by exploiting the back reflection from the substrate. The horizontal interference patterns the ridges of the hierarchical Christmas tree like structure. The artificial Morpho replica produced with this technique feature a brilliant blue iridescence up to an incident angle of 40 • .

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“…Moreover, in order to fabricated multilayer plasmonic structures, the electron beam lithography process is very complicated and time consuming. For fabricating micro-and nanostructures with high throughput and efficiency, the laser direct writing (LDW) technique is one of the best candidates [17][18][19][20][21][22][23][24][25]. Recently, the LDW technique has been successfully applied to fabricate metamaterials [26,27] and plasmonic devices [28,29].…”

Section: Introductionmentioning

confidence: 99%

Fabrication of multilayer metamaterials by femtosecond laser‐induced forward‐transfer technique

Tseng

Sun

et al. 2012

Laser & Photonics Reviews

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A novel method based on femtosecond laser‐induced forward transfer for high‐throughput and efficient fabrication of periodic multilayer plasmonic metamaterials is demonstrated. With precisely controlling laser raster path applied on sputtered multilayer thin films, the laser‐ablated materials can be transferred to another substrate leaving the fabricated multilayer structure on the original substrate. Subsequently, three‐dimensional metamaterials can be made by multilayer structuring. Moreover, all the experimental results show that to create such multilayer split resonant rings (SRRs) with uniform profile, the laser fluence should be fine controlled under proper conditions. The optical property of fabricated multilayer SRR array is investigated by optical measurements and finite‐difference time‐domain simulations, showing various resonant modes in the middle‐IR region. The calculated induced current distributions exhibit rich resonance properties of the structures as well. This work markedly extends the laser direct writing technique to a wide application in fabricating complicated metamaterials and plasmonic devices efficiently.

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Interference lithography: a powerful tool for fabricating periodic structures

Cited by 268 publications

References 86 publications

Fabrication of sub-10 nm gap arrays over large areas for plasmonic sensors

Fabrication of sub-10 nm gap arrays over large areas for plasmonic sensors

Fabrication of hierarchical photonic nanostructures inspired by Morpho butterflies utilizing laser interference lithography

Fabrication of multilayer metamaterials by femtosecond laser‐induced forward‐transfer technique

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