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Selective Ultrasensitive Optical Fiber Nanosensors Based on Plasmon Resonance Energy Transfer

Javier Barroso, Ángel Ortega-Gomez, Alba Calatayud‐Sanchez, Joseba Zubía, Fernando Benito‐Lopez, Joel Villatoro, Lourdes Basabe‐Desmonts

2020ACS Sensors21 citationsDOIOpen Access PDF

Abstract

The facet of optical fibers coated with nanostructures enables the development of ultraminiature and sensitive (bio)chemical sensors. The sensors reported until now lack specificity, and the fabrication methods offer poor reproducibility. Here, we demonstrate that by transforming the facet of conventional multimode optical fibers onto plasmon resonance energy transfer antenna surfaces, the specificity issues may be overcome. To do so, a low-cost chemical approach was developed to immobilize gold nanoparticles on the optical fiber facet in a reproducible and controlled manner. Our nanosensors are highly selective as plasmon resonance energy transfer is a nanospectroscopic effect that only occurs when the resonance wavelength of the nanoparticles matches that of the target parameter. As an example, we demonstrate the selective detection of picomolar concentrations of copper ions in water. Our sensor is 1000 times more sensitive than the state-of-the-art technologies. An additional advantage of our nanosensors is their simple interrogation; it comprises of a low-power light-emitting diode, a multimode optical fiber coupler, and a miniature spectrometer. We believe that the plasmon resonance energy transfer-based fiber-optic platform reported here may pave the way for the development of a new generation of ultraminiature, portable, and hypersensitive and selective (bio)chemical sensors.

Topics & Concepts

NanosensorSurface plasmon resonanceOptical fiberMaterials scienceFiber optic sensorPlasmonMulti-mode optical fiberNanotechnologyOptoelectronicsNanoparticleFörster resonance energy transferFiberOpticsFluorescencePhysicsComposite materialGold and Silver Nanoparticles Synthesis and ApplicationsAdvanced biosensing and bioanalysis techniquesBiosensors and Analytical Detection