Highly Sensitive Biosensing Using Arrays of Plasmonic Au Nanodisks Realized by Nanoimprint Lithography

Lee, Seung-Woo; Lee, Kyeong-Seok; Ahn, Junhyoung; Lee, Jaejong; Kim, Min-Gon; Shin, Yong‐Beom

doi:10.1021/nn102041m

Cited by 264 publications

(186 citation statements)

References 30 publications

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“…A sensitivity of 165 nm per refractive index unit (RIU) has been observed at the liquid mode λT and a sensitivity of 130 nm/RIU has been observed at the LiNbO3 mode λB. The sensitivity for the liquid mode is comparable to other similar SPR sensors on isotropic media with a resonance in the same wavelength range 18 -for these, the sensitivity increases for longer resonant wavelengths, 21 but this principle only applies due to the similarity of substrate and superstrate refractive indices and yields only one broad resonance: for our structure it does not hold true for the higher wavelength λB mode compared to λT. In essence, it can be inferred that it is the liquid (top) resonance mode λT which provides the high sensitivity and undergoes a sensitivity increase for longer wavelengths.…”

mentioning

confidence: 50%

Plasmonic gold nanodiscs using piezoelectric substrate birefringence for liquid sensing

Hao

Kenney

Cumming

2016

Applied Physics Letters

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This article presents the simulation, fabrication, and experimental characterization of a surface plasmonic resonance (SPR) sensor integrated with an acoustic sensing compatible substrate. The SPR sensor is designed to work in the visible region with gold nanodisc arrays fabricated on LiNbO3, which is both piezoelectric and birefringent. A linear relationship between resonance wavelength and varying liquid refractive indices were observed in experiments, and a sensitivity of 165nm/RIU was obtained. Polarization effects of the birefringent property of the Ycut LiNbO3 substrate have been investigated, which can also be applied to X-cut LiNbO3. Our study demonstrates the feasibility of an SPR sensor device utilizing a birefringent substrate, which has acoustic wave compatibility and can pave the way towards much more robust and flexible biosensing devices.

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confidence: 50%

Plasmonic gold nanodiscs using piezoelectric substrate birefringence for liquid sensing

Hao

Kenney

Cumming

2016

Applied Physics Letters

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“…In recent years, extensive efforts have been focused on the development of inexpensive, large area SERS substrates with high enhancement factors (EFs), and reproducible, uniform responses. [3][4][5][6][7] Current dominant fabrication techniques include electron beam (e-beam) lithography, [ 8,9 ] nanoimprint, [10][11][12] self-assembled nanosphere, [13][14][15][16][17] hybrid volumes. Therefore, a single substrate can work for almost "all" available excitation wavelengths, which is particularly useful for sensing a broad spectrum of chemicals on the same chip.…”

Section: Introductionmentioning

confidence: 99%

Ultrabroadband Metasurface for Efficient Light Trapping and Localization: A Universal Surface‐Enhanced Raman Spectroscopy Substrate for “All” Excitation Wavelengths

Zhang

Liu

et al. 2015

Adv Materials Inter

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nanoporous lithography methods, [18][19][20][21] etc. However, these techniques are still expensive and complicated for the fabrication of high quality SERS substrates over large areas, thus resulting in high prices for commercial SERS substrates. Furthermore, most commercial SERS substrates can only work for individual excitation wavelengths, i.e., one particular product works at one or two excitation wavelengths only. [22][23][24][25][26][27][28] When one wants to identify anonymous trace molecules or mixed samples, multiple excitation wavelengths will be required. [29][30][31] In this case, different substrates have to be used for different wavelength excitation, which consumes more biological/chemical materials, substrates, and measurement time. This is an obvious disadvantage for conventional SERS substrates. On the contrary, the SERS EF is proportional to the product of the fi eld intensity enhancements at both excitation and Raman scattering wavelengths. It was predicted that the maximum SERS enhancement can be achieved when localized surface plasmon resonance is located between the excitation and Raman scattering wavelengths. [ 32 ] To realize higher EF, double-resonance SERS substrates were proposed to realize strong enhancements for excitation and Raman scattered signals simultaneously using expensive e-beam lithography processes. [ 23 ] Due to the narrowband absorption spectra for both resonant bands, the enhanced SERS signal is still limited within narrow spectral regions. To address this problem, broadband resonant nanostructures are highly desired. For instance, a relatively broadband 1D metal-dielectric-metal metasurface (i.e., ≈70% optical absorption from 420 to 550 nm) was fabricated using e-beam lithography to realize uniform enhancement for SERS sensing. [ 24 ] However, the top-down lithography technique imposed a signifi cant fabrication cost barrier for large-scale practical applications. In addition, 1D grating structures are polarization dependent which can only work for given polarization states (usually transverse magnetic polarization). To overcome these limitations, here we report an ultrabroadband super absorbing metasurface substrate that can enhance the SERS signal for excitation wavelengths in a broad spectral region using lithography-free processes. [ 33 ] Most frequently used excitation wavelengths for SERS (e.g., from 450 to 1100 nm [23][24][25][26][27][28]34 ] are all covered due to the broadband light trapping and fi eld concentration within deep subwavelength Most reported surface-enhanced Raman spectroscopy (SERS) substrates can work for individual excitation wavelengths only. Therefore, different substrates have to be used for different excitation wavelengths, which consumes more biological/chemical materials, substrates, and measurement time. Here, an ultrabroadband super absorbing metasurface that can work as a universal substrate for low cost and high performance SERS sensing is reported. Due to broadband light trapping and localized fi eld enhancement, this structure can...

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“…5 As an alternative to photolithography processes to obtain various nanostructures, ultraviolet curing nanoimprint lithography has been proposed and pursued in creating nanostructures. [6][7][8][9][10][11] Ultraviolet curing nanoimprint lithography has existed for several years and has demonstrated great potential for advanced electronic nanofabrication endeavors in the industrial production of many semiconductors, hard disk drive storage devices, light-emitting diodes, solar cell devices, actuators, biosensors, and microelectro mechanical systems. Ultraviolet curing nanoimprint lithography to yield optical structures is being pursued in optics and photonics to yield low-cost optical components.…”

Section: Introductionmentioning

confidence: 99%

Ecofriendly antiglare film derived from biomass using ultraviolet curing nanoimprint lithography for high-definition display

Takei

Murakami²,

Mori³

et al. 2013

J. Micro/Nanolith. MEMS MOEMS

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Abstract. Nanopatterning of an ecofriendly antiglare film derived from biomass using an ultraviolet curing nanoimprint lithography is reported. Developed sugar-related organic compounds with liquid glucose and trehalose derivatives derived from biomass produced high-quality imprint images of pillar patterns with a 230-nm diameter. Ecofriendly antiglare film with liquid glucose and trehalose derivatives derived from biomass was indicated to achieve the real refraction index of 1.45 to 1.53 at 350 to 800 nm, low imaginary refractive index of <0.005 and low volumetric shrinkage of 4.8% during ultraviolet irradiation. A distinctive bulky glucose structure in glucose and trehalose derivatives was considered to be effective for minimizing the volumetric shrinkage of resist film during ultraviolet irradiation, in addition to suitable optical properties for high-definition display.

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Highly Sensitive Biosensing Using Arrays of Plasmonic Au Nanodisks Realized by Nanoimprint Lithography

Cited by 264 publications

References 30 publications

Plasmonic gold nanodiscs using piezoelectric substrate birefringence for liquid sensing

Plasmonic gold nanodiscs using piezoelectric substrate birefringence for liquid sensing

Ultrabroadband Metasurface for Efficient Light Trapping and Localization: A Universal Surface‐Enhanced Raman Spectroscopy Substrate for “All” Excitation Wavelengths

Ecofriendly antiglare film derived from biomass using ultraviolet curing nanoimprint lithography for high-definition display

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