High sensitivity nanoparticle detection using optical microcavities

High sensitivity nanoparticle detection using optical microcavities

We demonstrate a highly sensitive nanoparticle and virus detection method by using a thermal-stabilized reference interferometer in conjunction with an ultrahigh-Q microcavity. Sensitivity is sufficient to resolve shifts caused by binding of individual nanobeads in solution down to a record radius o...

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Veröffentlicht in:Proceedings of the National Academy of Sciences - PNAS 2011-04, Vol.108 (15), p.5976-5979
Hauptverfasser: Lu, Tao, Lee, Hansuek, Chen, Tong, Herchak, Steven, Kim, Ji-Hun, Fraser, Scott E., Flagan, Richard C., Vahala, Kerry, Yariv, Amnon
Format: Artikel
Sprache:eng
Schlagworte:
Binding sites
Biological Sciences
Biosensing Techniques
Electric potential
Humans
Influenza
Influenza A virus - isolation & purification
Interferometers
Interferometry - methods
Lasers
Molecules
Nanoparticles
Particle resonance
Particle Size
Physical Sciences
Polystyrenes
Proteins
Resonators
Sensitivity and Specificity
Signal to noise ratio
Supernova remnants
Virion - isolation & purification
Viruses - isolation & purification
Wavelengths
Whispering gallery waves
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Beschreibung
Zusammenfassung:We demonstrate a highly sensitive nanoparticle and virus detection method by using a thermal-stabilized reference interferometer in conjunction with an ultrahigh-Q microcavity. Sensitivity is sufficient to resolve shifts caused by binding of individual nanobeads in solution down to a record radius of 12.5 nm, a size approaching that of single protein molecules. A histogram of wavelength shift versus nanoparticle radius shows that particle size can be inferred from shift maxima. Additionally, the signal-to-noise ratio for detection of Influenza A virus is enhanced to 38:1 from the previously reported 3:1. The method does not use feedback stabilization of the probe laser. It is also observed that the conjunction of particle-induced backscatter and optical-path-induced shifts can be used to enhance detection signal-to-noise.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1017962108