Probing the limits of plasmonic enhancement using a two-dimensional atomic crystal probe

Chen, Wen; Zhang, Shunping; Meng, Kun; Liu, Weikang; Ou, Zhenwei; Li, Yang; Zhang, Yexin; Guan, Zhiqiang; Xu, Hongxing

doi:10.1038/s41377-018-0056-3

Cited by 105 publications

(123 citation statements)

References 48 publications

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“…Figure S6 in the Supporting Information is straight out of the FDTD software to show the maximum electric field enhancement that the CNGAs can perform, the white dotted lines indicate the position of a crescent nanogap. This result is consistent with previous reports and supported by the Maxwell's equations . The minimum G was set to be 1 nm considering that G ≥ 1 nm correspond to the classical regime, where the gap plasmonic modes is explained by the local Maxwell's equations.…”

Section: Resultssupporting

confidence: 88%

“…To achieve the extremely concentrated and strong electric fields, lots of efforts are contributed to fabricate kinds of plasmonic structures, revealing that sub‐10 nm nanogap and nanotip are the two key characteristics . In theory, as predicted by Maxwell's equations, the electric fields would become stronger with the decreasing distance between metal nanostructures and can be confined in the gaps; for nanotips, more electrons are distributed at the structural features with high curvature and thus lead to stronger electric fields …”

Section: Introductionmentioning

confidence: 99%

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Integrated “Hot Spots”: Tunable Sub‐10 nm Crescent Nanogap Arrays

Zhang

Wang

et al. 2019

Advanced Optical Materials

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trapping, [5] single-molecule analysis, [6,7] surface plasmon (SP) enhanced spectroscopy. [6,8,9] To achieve the extremely concentrated and strong electric fields, lots of efforts are contributed to fabricate kinds of plasmonic structures, revealing that sub-10 nm nanogap and nanotip are the two key characteristics. [10,11] In theory, as predicted by Maxwell's equations, the electric fields would become stronger with the decreasing distance between metal nanostructures and can be confined in the gaps; [12][13][14][15][16][17][18][19][20][21] for nanotips, more electrons are distributed at the structural features with high curvature and thus lead to stronger electric fields. [22][23][24][25][26][27][28][29][30] Various plasmonic nanostructures with either nanogaps or nanotips have been fabricated, successfully enhancing the electric fields to several orders of magnitude and confining them in extremely small areas. To obtain better performances, a natural thought is to include both nanogaps and nanotips in one plasmonic nanostructure, i.e., integrated "hot spots." Impressive efforts have been made to develop the multifeature nanostructures. For example, spilt-wedge antenna structures with sub-5 nm gaps, [10] 3D sub-10 nm nanostar dimers gap, [6] and 3D sub-10 nm Ag/SiN x gap with an pair of uniform tips, [31] have been fabricated and highly boosted the local optical field intensity. The fabrication of most these structures has primarily relied on electron beam lithography (EBL) [6,[32][33][34] and focused-ion beam (FIB). [35] These techniques can facilely control the patterns and precisely tune the size and separation, but they suffer from the drawbacks of high-cost, time-consuming, and low-throughput. It is urgently needed to develop a simple and scalable process for their production.Nanoskiving, that combines the deposition of thin metal layers on substrates (flat or structured) and sectioning using a unity of ultramicrotome and diamond knife, would be an alternative fabrication technique for plasmonic nanostructures with both nanogaps and nanotips. [36][37][38][39] Compared with the conventional fabrication techniques (EBL and FIB), nanoskiving is uncomplicated, fast, and scalable, requiring no sophisticated equipment. Nanoskiving has been widely used in fabricating numerous nanostructures, showing the strong capability for nanostructures on-demand. In particular, our research group has reported 3D zig-zag nanowires that possess both nanogaps and nanotips via combining photolithography Plasmonic crescent nanogap arrays (CNGAs) integrated by nanoscale gaps and nanotips exhibit strong capability of light confinement and thus lead to extremely electric field enhancement. The CNGAs with tunable gap-width are fabricated via a low-cost and simple process combining colloidal lithography and nanoskiving techniques. Incident light is captured in the nanogaps and at the two tips of nanocrescent, where extremely strong electric fields are excited. The strong electric fields lead to greatly enhanced surface-enhanced Raman s...

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Section: Resultssupporting

confidence: 88%

Section: Introductionmentioning

confidence: 99%

Integrated “Hot Spots”: Tunable Sub‐10 nm Crescent Nanogap Arrays

Zhang

Wang

et al. 2019

Advanced Optical Materials

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“…[6][7][8][9] Among them, SERS is an extensively studied analytical tool that provides molecule-specific information on the molecular structure and chemical composition of analytes through Raman scattering. It is now generally accepted that the SERS enhancement arises from the enlarged local electromagnetic (EM) fields near a nanostructured metal system, which is resulted from localized surface plasmon resonances (LPRs), 10 known as plasmonic "hot-spots" that occur near sharp asperities and in nanometer gaps between metal nanostructures such as nanoparticles (NPs), 11,12 NP-spacer-film systems, 13,14 etc. Generally, the number and intensity of plasmonic hot-spots largely determines the SERS capability of a given substrate.…”

Section: Introductionmentioning

confidence: 99%

Broadband SERS detection with disordered plasmonic hybrid aggregates

et al. 2020

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“…This is even more critical for LSPR detection using clusters of noble metal nanoparticles, where coupling of electronic oscillations among the adjacent nanoparticles generates plasmonic "hotspots" [11,12]. With a more than 10 6 -fold enhancement of the electromagnetic field, plasmonic hotspots have emerged as a cornerstone of a wide range of applications for surface-enhanced spectroscopies [13][14][15]. For instance, sensitivity down to the single molecule level has been achieved by surface-enhanced Raman spectroscopy [16,17].…”

Section: Introductionmentioning

confidence: 99%

Self-assembly of robust gold nanoparticle monolayer architectures for quantitative protein interaction analysis by LSPR spectroscopy

et al. 2020

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Localized surface plasmon resonance (LSPR) detection offers highly sensitive label-free detection of biomolecular interactions. Simple and robust surface architectures compatible with real-time detection in a flow-through system are required for broad application in quantitative interaction analysis. Here, we established self-assembly of a functionalized gold nanoparticle (AuNP) monolayer on a glass substrate for stable, yet reversible immobilization of Histidine-tagged proteins. To this end, one-step coating of glass substrates with poly-L-lysine graft poly(ethylene glycol) functionalized with ortho-pyridyl disulfide (PLL-PEG-OPSS) was employed as a reactive, yet biocompatible monolayer to self-assemble AuNP into a LSPR active monolayer. Site-specific, reversible immobilization of His-tagged proteins was accomplished by coating the AuNP monolayer with tris-nitrilotriacetic acid (trisNTA) PEG disulfide. LSPR spectroscopy detection of protein binding on these biocompatible functionalized AuNP monolayers confirms high stability under various harsh analytical conditions. These features were successfully employed to demonstrate unbiased kinetic analysis of cytokine-receptor interactions. Keywords Localized surface plasmon resonance (LSPR). Self-assembly. Real-time biosensor. Protein immobilization. Quantitative interaction analysis. Kinetics Abbreviations AuNP Gold nanoparticle HaloTag-NB HaloTag fused with anti-GFP nanobody HTL HaloTag ligand IFNAR2 Type I interferon receptor subunit 2 IFNα2 I n t e r f e r o n-α2 LSPR Localized surface plasmon resonance mEGFP Monomeric enhanced green fluorescent protein PLL-PEG-OPSS Poly-L-lysine graft poly(ethylene glycol) terminated with ortho-pyridyl disulfide TrisNTA Tris-nitrilotriacetic acid Published in the topical collection Advances in Direct Optical Detection with guest editors Antje J. Baeumner, Günter Gauglitz, and Jiri Homola.

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Probing the limits of plasmonic enhancement using a two-dimensional atomic crystal probe

Cited by 105 publications

References 48 publications

Integrated “Hot Spots”: Tunable Sub‐10 nm Crescent Nanogap Arrays

Integrated “Hot Spots”: Tunable Sub‐10 nm Crescent Nanogap Arrays

Broadband SERS detection with disordered plasmonic hybrid aggregates

Self-assembly of robust gold nanoparticle monolayer architectures for quantitative protein interaction analysis by LSPR spectroscopy

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