Plasmonic Biosensor Based on Vertical Arrays of Gold Nanoantennas

Klinghammer, Stephanie; Uhlig, Tobias; Patrovsky, Fabian; Böhm, Matthias; Schütt, Julian; Pütz, Nils; Baraban, Larysa; Eng, Lukas M.; Cuniberti, Gianaurelio

doi:10.1021/acssensors.8b00315

Cited by 42 publications

(37 citation statements)

References 67 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Compared to SPR, an optical phenomenon on large metal structures, localized SPR (LSPR) is a phenomenon that occurs on metallic nanostructures 63. When an incident light is introduced to the metallic nanostructure, the electromagnetic field of the light induces collective electron charge oscillations confined in the metallic nanostructure, and consequently leads to an absorbance of light within the ultraviolet-visible (UV-VIS) band.…”

Section: Applications Of Biosensorsmentioning

confidence: 99%

Recent Advances in Biosensors for Nucleic Acid and Exosome Detection

Zhang

Lai

2019

Chonnam Med J

View full text Add to dashboard Cite

Biosensors are analytical devices for biomolecule detection that compromise three essential components: recognition moiety, transducer, and signal processor. The sensor converts biomolecule recognition to detectable signals, which has been applied in diverse fields such as clinical monitoring, in vitro diagnostics, food industry etc. Based on signal transduction mechanisms, biosensors can be categorized into three major types: optical biosensors, electrochemical biosensors, and mass-based biosensors. Recently, the need for faster, more sensitive detection of biomolecules has compeled researchers to develop various sensing techniques. In this review, the basic structure and sensing principles of biosensors are introduced. Additionally, the review discusses multiple recent works about nucleic acid and exosome sensing.

show abstract

Section: Applications Of Biosensorsmentioning

confidence: 99%

Recent Advances in Biosensors for Nucleic Acid and Exosome Detection

Zhang

Lai

2019

Chonnam Med J

View full text Add to dashboard Cite

show abstract

“…Step 4: Given the light extinction spectrum of the sample, identify the laser wavelength that corresponds to the value of n i which, when substituted to Equation (8), allows sensitivity to reach its optimal value S opt .…”

Section: Optimization Protocolmentioning

confidence: 99%

“…Refractive index sensors are intensely investigated for numerous biomedical [1][2][3], chemical [4,5] and industrial [6,7] applications. An indicative yet far from exhaustive list of sensing mechanisms relies on plasmonic [8][9][10][11], photonic crystal [12][13][14][15], micro-cavity [16][17][18][19], optical fiber [20][21][22][23] and wave-guide [24][25][26][27] configurations. Associated with Fresnel reflectance properties at planar interfaces, differential refractometry offers an alternative path to sensing refractive index changes, by exploitation of interference [28], deflection [29] or (more relevant to the present work) critical-angle [30][31][32][33][34][35] effects.…”

Section: Introductionmentioning

confidence: 99%

Critical-Angle Differential Refractometry of Lossy Media: A Theoretical Study and Practical Design Issues

et al. 2019

View full text Add to dashboard Cite

At a critical angle of incidence, Fresnel reflectance at an interface between a fronttransparent and a rear lossy medium exhibits sensitive dependencies on the complex refractiveindex of the latter. This effect facilitates the design of optical sensors exploiting single (or multiple)reflections inside a prism (or a parallel plate). We determine an empirical framework that capturesperformance specifications of this sensing scheme, including sensitivity, detection limit, range oflinearity and—what we define here as—angular acceptance bandwidth. Subsequently, we developan optimization protocol that accounts for all relevant optical or geometrical variables and that canbe utilized in any application.

show abstract

“…Plasmonic nanostructures have attracted considerable attention due to their ability to manipulate light and their potential for widespread applications, such as surface enhanced spectroscopies, [ 1–6 ] biosensors, [ 7–9 ] and nonlinear optics. [ 10–12 ] A currently fast developing area in plasmonics is metal nanoparticles.…”

Section: Introductionmentioning

confidence: 99%

Engineering Colloidal Lithography and Nanoskiving to Fabricate Rows of Opposing Crescent Nanogaps

Zhang

Zhao

et al. 2020

Advanced Optical Materials

View full text Add to dashboard Cite

A scalable fabrication route combining colloidal lithography and nanoskiving is reported for generating free‐standing asymmetric metal nanostructures of crescent‐shaped gold nanowires and rows of opposing crescents with and without nanogaps. Strong localized surface plasmon resonances and propagating surface plasmon polaritons are excited at the sharp tips of the crescent and in the sub‐10 nm nanogaps. High‐order resonance modes are excited due to the coupling between the resonances in the tips and gaps. The Raman signals are greatly enhanced due to the strong electric fields. In addition, the optical responses and electric field distributions can be controlled by the polarization of the incident light. The strong electric field enhancement coupled with facile, scalable fabrication make crescent‐shaped nanostructures promising in nonlinear optics, optical trapping, and surface‐enhanced spectroscopy.

show abstract

Plasmonic Biosensor Based on Vertical Arrays of Gold Nanoantennas

Cited by 42 publications

References 67 publications

Recent Advances in Biosensors for Nucleic Acid and Exosome Detection

Recent Advances in Biosensors for Nucleic Acid and Exosome Detection

Critical-Angle Differential Refractometry of Lossy Media: A Theoretical Study and Practical Design Issues

Engineering Colloidal Lithography and Nanoskiving to Fabricate Rows of Opposing Crescent Nanogaps

Contact Info

Product

Resources

About