Multiarchitecture-Based Plasmonic-Coupled Emission Employing Gold Nanoparticles: An Efficient Fluorescence Modulation and Biosensing Platform

Xie, Kai‐Xin; Liu, Chang; Liu, Qian; Xiao, Xiu-Xian; Li, Zhuan; Li, Mengfan

doi:10.1021/acs.langmuir.1c01965

Cited by 13 publications

(23 citation statements)

References 38 publications

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“…Furthermore, our laboratory has examined the plasmonic interfacial functionality (basic research) of a variety of nanoscale materials in the SPCE platform toward applied optics and translational-based photonic biosensors. − In the past decade, several quintessential processes, material properties, and applications have been reported in SPCE. The study of materials such as plasmonic NPs (Ag, Au, Pt, and Pd), CNTs, low-dimensional carbon (0D, 1D, and 2D), plasmon-soliton architectures, high-refractive-index dielectric NPs and their plasmonic hybrids, to name a few, has enriched the understanding of the quantum emitter–photon coupling phenomenon in the nano regime. − Although there are different routes to synthesize varied NPs, the utility of nanoassemblies in SPCE had remained elusive on account of the nanogaps supported by them. Self-assembly is a widely used technique for the synthesis of nanoassemblies with collective functional properties .…”

Section: Introductionmentioning

confidence: 99%

“…(ii) AuNPs, by virtue of interband transitions and ohmic losses, quench the molecular emission from radiating dipoles present in their vicinity. Different methodologies have been explored in the past to overcome the quenching phenomenon. ,− Here, dequenching the intrinsically quenched emission in the presence of AuNPs using Au-based CSs is presented. The intense and uniform 3D electromagnetic hotspots rendered delocalized and localized plasmons, thereby surmounting the quenching phenomenon.…”

Section: Introductionmentioning

confidence: 99%

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Hottest Hotspots from the Coldest Cold: Welcome to Nano 4.0

Rai

Bhaskar

Ganesh

et al. 2022

ACS Appl. Nano Mater.

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Conventionally, nanoassemblies are synthesized using widely adopted template-based approaches. External stimuli such as electric and magnetic fields and light-induced reactions have recently been investigated. The exploration using a temperature gradient in this spotlight is very nascent. In this context, soret colloids are nanoparticle (NP) assemblies obtained via adiabatic cooling at −18 °C. They have found widespread utility in surface plasmon-coupled emission (SPCE) and surface-enhanced Raman scattering (SERS) for sensing analytes and ions of biological and environmental concern. However, the drawback of the current methodology for obtaining enhanced tunability in functional properties for large-scale production has remained a bottleneck hitherto on account of the significant time (2 h) needed for building precise nanoassemblies. In this direction, a rapid, one-pot, and cost-effective adiabatic cooling methodology to obtain precise nanoassemblies with exceptionally tunable optical and morphological properties is experimentally demonstrated in this work. Thermodiffusion of homogeneous gold (Au) and silver (Ag) nanoparticles using adiabatic cooling at cryoshift temperatures (−80, −150, and −196 °C (or liquid N 2 )) significantly lowered the time from 2 h to 3 min for obtaining structurally and functionally tunable nanoassemblies. This methodology aids in the realization of hotspots of first, second, third, and fourth generations, which are nanoregimes of high electric-field intensity. The innovative fourth-generation hotspots (a horizon toward Nano 4.0) were distinctively generated and studied by mounting the cryosorets on SPCE substrates. The dual dependence of nanoassembly formation on time and cooling temperature is elaborately discussed for the first time in this study. The abundant field intensity and synergistic plasmon hybridization between metallic Ag, dielectric TiO 2 nanorods, and graphene oxide π-plasmons assisted in the realization of single-molecule detection. The sensing is achieved using a cost-effective smartphone-based technology that is amenable to resource-limited settings. This work opens a window to accomplish precise nanoassemblies of different sizes, shapes, material properties, numbers of particles by modulating the adiabatic cooling time and temperature, for use in biosensing, photonics, and interdisciplinary applications.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Hottest Hotspots from the Coldest Cold: Welcome to Nano 4.0

Rai

Bhaskar

Ganesh

et al. 2022

ACS Appl. Nano Mater.

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“…These studies unambiguously pointed to the advantages of the engineered morphologies with sharp edges (such as nanostars, nanoprims, and nanorods) and their hierarchical assemblies for providing high electromagnetic (EM) field confinement, leading to enhanced SPCE. − Our earlier studies in this direction contributed to this by reaffirming the structural advantages of nanovoids and nano-cavities for achieving significant plasmon-based enhancements. − These, in turn, have been utilized for ultrasensitive and reliable analytical detection through both vibrational Raman (SERS) and fluorescence (SPCE). − Furthermore, 118-fold SPCE enhancements have been demonstrated by minimizing Ohmic losses using high refraction index dielectrics in conjugation with metal nanostructures . In spite of such significant advancements in both fundamental aspects and the applications thereof, the major challenges in SPCE enhancements using metallic nanostructures have been (i) inevitable Ohmic losses along with radiative damping, ,, (ii) poor chemical stability, especially in real-time applications, ,, and (iii) extensive isotropic photon scattering that compromises the magnitude of SPCE enhancements. − As opposed to the variety of metal, non-metallic, dielectric, two-dimensional, and zero-dimensional substrates that have been investigated for SERS, substrates for SPCE have been primarily restricted to metallic and their composites. ,, Thus, a ubiquitous platform that synergistically couples the plasmonic advantages of metallic nanostructures while simultaneously minimizing the Ohmic and radiative losses is desirable for improving the quality factor and reliability of SPCE, thereby transforming it into a powerful ultrasensitive analytical technique. − Achieving this would provide distinct opportunities for portable and mobile phone-based detection capabilities catering to the internet-of-things. , …”

Section: Introductionmentioning

confidence: 84%

Metal–Dielectric Interfacial Engineering with Mesoporous Nano-Carbon Florets for 1000-Fold Fluorescence Enhancements: Smartphone-Enabled Visual Detection of Perindopril Erbumine at a Single-molecular Level

Bhaskar

Thacharakkal

Ramamurthy

et al. 2022

ACS Sustainable Chem. Eng.

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Metallic nanosystems with strong surface plasmon resonance have been a predominant choice for surface plasmoncoupled emission (SPCE), leading to a plethora of sensing and diagnostic applications. The Ohmic losses and strong isotropic scattering of the emissive photons in such systems still remain major challenges that limit the sensitivity, reliability, and magnitude of enhancements. Consequently, rational designing of nonplasmonic dielectric interfaces and their hybrids that suppress these drawbacks without compromising the radiative decay pathways is highly desirable. Here, we present dielectric-based nanostructured carbon florets (NCFs), exhibiting precisely tailored porosities and surface morphologies for enhanced light entrapment, thereby achieving plasmon-free generation of electromagnetic (EM) hotspots. The hard-carbon sp 2 framework of NCF, together with its morphology resembling conical microcavities, thus represents the first all-carbon system, providing 310-fold SPCE enhancements. Such enhancements achieved in cavity configuration present a fundamental departure from those obtained through conventional plasmonic interfaces that work best in spacer and extended cavities. This underlines the importance of the extensive surface area (745.62 m 2 /g) and high absorbance (>0.9) of NCF. Besides showcasing the detailed morphological dependence of SPCE, the NCF also acts as a versatile support for anchoring plasmonic Ag and interfacing with π-plasmon rich GO. Such a multi-component hybrid combines the benefits of several radiative pathways for realizing unprecedented 1000-fold SPCE enhancements. Consequently, this substrate has been utilized for the detection of pathologically important PE at single-molecular attomolar levels (1 × 10 −19 M) with excellent linearity (R 2 = 0.996) and high reliability (RSD: 2.07) over a wide concentration range spanning 16 orders of magnitude (0.1 aM−1 mM). The demonstration of such detection with smartphone-based platforms expands opportunities for the internet-of-things, besides unraveling newer possibilities for metal−dielectric interfacial engineering.

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“…Recently, anisotropic Ag and Au nanomaterials with sharp edges, vertices, and cavities have been gaining increased attention for hotspot generation in plasmonics-based optical sensors. − However, it is important to note that both Ag and AuNPs have typical merits and demerits from a spectro-plasmonics point of view. − While AgNPs suffer from unavoidable chemical instability (absent in AuNPs), the usage of AuNPs in SPCE has remained a long-standing challenge on account of the well-known quenching phenomena (due to high Ohmic losses) in spite of their copious electron density (≈5.90 × 10 16 m –3 ). ,, In this context, fundamental explorations have been limited to Ag-based nanomaterials or composites due to comparatively negligible quenching rendered by them with the use of rhodamine moieties as luminophores. In the spatial range of <5 nm, the so-called zone of inactivity is prevalent in the case of gold due to large non-radiative decay channels supported by higher-order plasmonic modes. , In order to overcome such limitation of quenching with AuNPs, different approaches have been adopted, namely, (i) plasmon intermixing in nanocavities where the quenching is dequenched, (ii) core–shell metal–dielectric nanointerfaces, (iii) metal–dielectric-decorated nanorchitectures, (iv) nanostructures showcasing sharp protrusions such as tips and vertices supporting tip–core hybrid plasmon coupling, and (v) nanoshells and nanocages for generating cavity and void hotspots. , Although these strategies have demonstrated dequenched fluorescence emission, the synthetic routes adopted for nanofabrication are often not bio-inspired and not sustainable.…”

Section: Introductionmentioning

confidence: 99%

Sericin-Based Bio-Inspired Nano-Engineering of Heterometallic AgAu Nanocubes for Attomolar Mefenamic Acid Sensing in the Mobile Phone-Based Surface Plasmon-Coupled Interface

et al. 2022

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Engineering photo-plasmonic platforms with heterometallic nanohybrids are of paramount significance for realizing augmented sensitivity in fluorescence-based analytical detection. Although myriad nanomaterials with versatile functionalities have been explored in this regard in the surface plasmon-coupled emission (SPCE) interface, light harvesting using nano-antennas synthesized via sustainable bio-inspired routes still remains a high priority in current research. Our study provides a rational design for in situ fabrication of nanoparticles of silver, gold, and their plasmonic hybrids using biocompatible, non-hazardous sericin protein (obtained Bombyx mori) as the reducing and capping agent. The one-pot, user-eco-friendly technology demonstrated here utilizes UV irradiation to promote the photo-induced electron transfer mechanism, thereby yielding nanomaterials of tunable optoelectronic functionalities. The resulting homometallic and heterometallic nanohybrids with robust localized surface plasmon resonances (LSPR) showed strong light-confining attributes when interfaced with the propagating surface plasmon polaritons (SPPs) of the SPCE platform, thereby yielding tunable, highly directional, polarized, and amplified fluorescence emission. The experimentally obtained emission profiles displayed an excellent correlation with the theoretically obtained dispersion diagrams validating the spectro-plasmonic results. The abundant hotspots from AgAu nanocubes presented in excess of 1300-fold dequenched fluorescence enhancement and were utilized for cost-effective and real-time mobile phone-based sensing of biologically relevant mefenamic acid at an attomolar limit of detection. We believe that this superior biosensing performance accomplished using the frugal bioinspired nano-engineering at hybrid interfaces would open new doors for developing nanofabrication protocols with the quintessential awareness of the principles of green nanotechnology, consequently eliminating hazardous chemicals and solvents in the development of point-of-care diagnostic tools.

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Multiarchitecture-Based Plasmonic-Coupled Emission Employing Gold Nanoparticles: An Efficient Fluorescence Modulation and Biosensing Platform

Cited by 13 publications

References 38 publications

Hottest Hotspots from the Coldest Cold: Welcome to Nano 4.0

Hottest Hotspots from the Coldest Cold: Welcome to Nano 4.0

Metal–Dielectric Interfacial Engineering with Mesoporous Nano-Carbon Florets for 1000-Fold Fluorescence Enhancements: Smartphone-Enabled Visual Detection of Perindopril Erbumine at a Single-molecular Level

Sericin-Based Bio-Inspired Nano-Engineering of Heterometallic AgAu Nanocubes for Attomolar Mefenamic Acid Sensing in the Mobile Phone-Based Surface Plasmon-Coupled Interface

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