2023
DOI: 10.3390/s23073455
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“Grafting-To” Covalent Binding of Plasmonic Nanoparticles onto Silica WGM Microresonators: Mechanically Robust Single-Molecule Sensors and Determination of Activation Energies from Single-Particle Events

Abstract: We hereby present a novel “grafting-to”-like approach for the covalent attachment of plasmonic nanoparticles (PNPs) onto whispering gallery mode (WGM) silica microresonators. Mechanically stable optoplasmonic microresonators were employed for sensing single-particle and single-molecule interactions in real time, allowing for the differentiation between binding and non-binding events. An approximated value of the activation energy for the silanization reaction occurring during the “grafting-to” approach was obt… Show more

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Cited by 4 publications
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“…The remarkable sensitivity of these WGM optical resonances to environmental changes arises from their evanescent fields at the surface of a microsphere that extend to the interaction with the surrounding solution. Microsphere WGM sensors have been widely deployed as biosensors, enabling the detection of protein monolayers, biomolecular interactions, bacteria, and nanoparticles. To push the boundary of detection sensitivity to its current highest single-molecule level to enable, for example, the detection of single atomic ions, plasmonic nanorods are strategically placed on the microspheres at the location of a WGM, as depicted in Figure a. These optoplasmonic WGM sensors capitalize on the evanescent field to excite plasmon resonance in plasmonic nanorods aligned with the electromagnetic field, leading to intensity enhancements at the nanorod tips; essentially placing the probing WGM field on the scale of the molecule, where only molecules interacting with the enhanced near-field region at the tips of the nanorods are detectable.…”
Section: Introductionmentioning
confidence: 99%
“…The remarkable sensitivity of these WGM optical resonances to environmental changes arises from their evanescent fields at the surface of a microsphere that extend to the interaction with the surrounding solution. Microsphere WGM sensors have been widely deployed as biosensors, enabling the detection of protein monolayers, biomolecular interactions, bacteria, and nanoparticles. To push the boundary of detection sensitivity to its current highest single-molecule level to enable, for example, the detection of single atomic ions, plasmonic nanorods are strategically placed on the microspheres at the location of a WGM, as depicted in Figure a. These optoplasmonic WGM sensors capitalize on the evanescent field to excite plasmon resonance in plasmonic nanorods aligned with the electromagnetic field, leading to intensity enhancements at the nanorod tips; essentially placing the probing WGM field on the scale of the molecule, where only molecules interacting with the enhanced near-field region at the tips of the nanorods are detectable.…”
Section: Introductionmentioning
confidence: 99%