LSPR‐Induced Catalytic Enhancement Using Bimetallic Copper Fabrics Prepared by Galvanic Replacement Reactions

Anderson, Samuel R.; O’Mullane, Anthony P.; Gaspera, Enrico Della; Ramanathan, Rajesh; Bansal, Vipul

doi:10.1002/admi.201900516

Cited by 13 publications

(4 citation statements)

References 72 publications

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“…In recent years, plasmon-driven enhancement of chemical reactivity has become an area of active investigation. ,,, While the LSPR eigenmodes within a particle can now be regularly probed using electron energy loss spectroscopy (EELS), − visualizing the spatially confined subparticle chemical reactivity is highly challenging. Thus, most of the plasmon-enhanced catalysis studies simply investigate the chemical reaction outcomes in bulk solutions on photoexcitation. , In a notable work, Maier’s group could probe the above LSPR-induced chemical transformation of 4-NTP to 4-ATP on Ag nanoantennas with a 15 nm resolution (using electron microscopy) by covalently conjugating 15 nm Au nanoparticles selectively on the locations where chemical transformation of 4-NTP to 4-ATP took place . Other relevant studies that have investigated the influence of plasmon excitation on reaction site selectivity include use of polarized light to deposit PbO 2 on Au nanocuboids to form chiral particles, selective deposition of PbO 2 on the tips of Au nanorods, site-selective etching of Ag nanocubes deposited on the TiO 2 surface, and selective deposition of organic diazonium salts on the tips of a Au nanoprism …”

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confidence: 99%

Photomodulated Spatially Confined Chemical Reactivity in a Single Silver Nanoprism

et al. 2020

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Single-atom and single-particle catalysis is an area of considerable topical interest due to their potential in explaining important fundamental processes and applications across several areas. An interesting avenue in single-particle catalysis is spatial control of chemical reactivity within the particle by employing light as an external stimulus. To demonstrate this concept, we report galvanic replacement reactions (GRRs) as a spatial marker of subparticle chemical reactivity of a silver nanoprism with AuCl4 – ions under optical excitation. The location of a GRR within a single Ag nanoprism can be spatially controlled depending on the plasmon mode excited. This leads to chemomorphological transformation of Ag nanoprisms into interesting Ag–Au structures. This spatial biasing effect is attributed to localized hot electron injection from the tips and edges of the silver nanoprisms to the adjacent reactants that correlate with excitation of different surface plasmon modes. The study also employs low-energy-loss EELS mapping to additionally probe the spatially confined redox reaction within a silver nanoprism. The findings presented here allow the visualization of a plasmon-driven subparticle chemical transformation with high resolution. The selective optical excitation of surface plasmon eigenmodes of anisotropic nanoparticles offers opportunities to spatially modulate chemical transformations mediated by hot electron transfer.

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Photomodulated Spatially Confined Chemical Reactivity in a Single Silver Nanoprism

et al. 2020

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“…The UV-Vis spectra of AgNPs commonly exhibit a characteristic peak at 420 nm due to their strong surface plasmon resonance (SPR) effect. [27][28][29][30][31][32] The absorption and scattering characteristics of AgNPs can be altered by varying the particle size, shape, or refractive index near their surface. A noticeable blue shift compared with AgNPs absorption maxima is credited to C-shelling and a decrease in particle size, while a sharp peak intensity is attributed to the stability of nanoparticles.…”

Section: Discussionmentioning

confidence: 99%

“…The optical properties of the prepared nanomaterial were studied by UV–Vis spectroscopy (Figure 1a). The UV–Vis spectra of AgNPs commonly exhibit a characteristic peak at 420 nm due to their strong surface plasmon resonance (SPR) effect 27‐32 . The absorption and scattering characteristics of AgNPs can be altered by varying the particle size, shape, or refractive index near their surface.…”

Section: Discussionmentioning

confidence: 99%

A novel cellulosic non‐enzymatic nanosensor based on carbon shell silver (Ag@C) nanoparticles for colorimetric detection of Chlorpyrifos in agricultural products

et al. 2022

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Background: The precise detection and quantification of organophosphorus pesticides are highly required to ensure food safety. The non-enzymatic nanosensor technology has appeared as an efficient method to replace conventional analytical techniques of pesticide detection. The utilization of carbon-based nanomaterials and metal nanoparticles has shown great potential to develop non-enzymatic nanosensors for the sensitive and selective sensing of food contaminants.Results: In this study, bifunctional carbon shell silver nanoparticles (Ag@C NPs) having oxidase-like properties and advanced optical activities were used as nanozymes for visual detection of highly toxic organophosphorus pesticide (OP), Chlorpyrifos. The asprepared nanomaterial was characterized for its structural and morphological features.The nanosensor was fabricated by immobilizing Ag@C NPs in the network of sodium alginate gel over a cellulosic paper disc. The detection was based on the inhibition of oxidase-like activity of Ag@C NPs by the adsorption of pesticide which blocks the accessibility of substrate to produce the blue-colored product. Under the optimized conditions, the fabricated sensor showed potential analytical response for Chlorpyrifos providing a dynamic linear range from 0-350 ng/mL with a limit of detection, of 0.097 ng/mL and limit of quantification, of 0.293 ng/mL. In addition, the devised sensor was able to recover Chlorpyrifos from spiked wheat, apple, and water samples with excellent recovery percentages. Further, the constructed nanosensor exhibited excellent selectivity and specificity to Chlorpyrifos. Conclusion:The fabricated surface provides a rapid, selective, low cost and portable detection method for the real-time detection of OP traces from food and environmental samples.

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“…They can be synthesized through various methods, including thermal decomposition (Toshima and Yonezawa, 1998), microwave (Toshima and Yonezawa, 1998), seeded growth (Chen et al, 2013), co-reduction (Toshima and Yonezawa, 1998), and galvanic displacement (Bansal et al, 2008;Xia et al, 2013;Anderson et al, 2019;Bhanushali et al, 2020) nanozyme was fabricated for colorimetric glucose detection in urine using the galvanic displacement method, where Cu was used as a sacrificial template to enhance the ambient stability of the nanozyme (Naveen Prasad et al, 2022).…”

Section: Bimetallic Nanoparticle-based Nanozymesmentioning

confidence: 99%

Advances in Nanozymes as a Paradigm for Viral Diagnostics and Therapy

et al. 2023

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Over the last few decades, humankind has constantly encountered new viral species that create havoc in the socio-economic balance worldwide. Among the method to combat these novel viral infections, fast and Point-of-care diagnosis is of prime importance to contain the spreading of viral infections. However, most sensitive diagnostic systems for viral infections are time-consuming and require well-trained professionals, making it difficult for the patients. In recent years nanozymes emerged as promising therapeutic and fast diagnostic tools due to their multienzymelike catalytic performance. Nanozymes can be designed using inorganic or organic components with tailorable physicochemical surface properties, enabling the attachment of various molecules and species on the surface of the nanozyme for specific recognition. In addition to the composition, the multienzyme-like catalytic performance can be modulated by the shape and size of the nanoparticles. Due to their multicatalytic abilities, nanozymes can be used for fast diagnosis and therapy for viral infections. Here we attempt to focus on the insights and recent explorations on the advances in designing various types of nanozymes as a theranostic tool for viral infections.

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LSPR‐Induced Catalytic Enhancement Using Bimetallic Copper Fabrics Prepared by Galvanic Replacement Reactions

Cited by 13 publications

References 72 publications

Photomodulated Spatially Confined Chemical Reactivity in a Single Silver Nanoprism

Photomodulated Spatially Confined Chemical Reactivity in a Single Silver Nanoprism

A novel cellulosic non‐enzymatic nanosensor based on carbon shell silver (Ag@C) nanoparticles for colorimetric detection of Chlorpyrifos in agricultural products

Advances in Nanozymes as a Paradigm for Viral Diagnostics and Therapy

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