Detecting single viruses and nanoparticles using whispering gallery microlasers

He, Lina; Özdemir, Şahin Kaya; Zhu, Jian‐Gang; Kim, Woo-Sung; Yang, Lan

doi:10.1038/nnano.2011.99

Cited by 602 publications

(463 citation statements)

References 29 publications

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“…We believe that in the future, a differential detection scheme could cancel out drifts using a split mechanical mode similar to what is currently done in optical detection. 4 The optical quality factor, Q O , is measured using the resonance linewidth to be near 7310 6 . Moreover, this value of Q O is not affected by introducing water inside the bubble resonator.…”

Section: Cavity Optomechanics On a Microfluidic Resonator With Water mentioning

confidence: 99%

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Cavity optomechanics on a microfluidic resonator with water and viscous liquids

et al. 2013

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Currently, optical or mechanical resonances are commonly used in microfluidic research. However, optomechanical oscillations by light pressure were not shown with liquids. This is because replacing the surrounding air with water inherently increases the acoustical impedance and hence, the associated acoustical radiation losses. Here, we bridge between microfluidics and optomechanics by fabricating a hollow-bubble resonator with liquid inside and optically exciting vibrations with 100 MHz rates using only mW optical-input power. This constitutes the first time that any microfluidic system is optomechanically actuated. We further prove the feasibility of microfluidic optomechanics on liquids by demonstrating vibrations on organic fluids with viscous dissipation higher than blood viscosity while measuring density changes in the liquid via the vibration frequency shift. Our device will enable using cavity optomechanics for studying non-solid phases of matter, while light is easily coupled from the outer dry side of the capillary and fluid is provided using a standard syringe pump. Keywords: nonlinear optics; optical materials and devices; optomechanics INTRODUCTION A major application of optical resonators is in the field of sensing where microresonators were used to sense biomarkers in serum 1 and to detect viruses and nanoparticles 2-4 in an aqueous environment. With similar motivation and in a parallel effort, mechanical resonators were used to weigh biomolecules and cells. 5,6 Just like we use more than one sense (e.g., eyes and ears) to detect hazards, optomechanics might suggest a bridge between the seemingly parallel optical and mechanical detection fields. The recent availability of liquid containing bubble shaped resonators, 7,8 in combination with optomechanical vibrations at .GHz rate, 9-12 might pave the way for ultrasound investigations on analytes in liquids. Nevertheless, cavity optomechanics on non-solid phases of material was never before demonstrated.One of the major 'show stoppers' on the way to microfluidic optomechanics originates from the fact that water has acoustical impedance that is more than 4000 times larger than air. Hence, naively immersing optomechanical devices in water will accordingly increase the acoustical radiation losses. Liquid submerged optomechanical oscillators are therefore challenging, as sound will tend to escape from the cavity by radiating out rather than being confined to the resonator. Here, we confine the high-impedance water inside 6,13 a silica-bubble resonator so that its acoustical quality factor is minimally affected. In this manner, when both mechanical and optical quality factors, Q m and Q O , of microdevices are sufficiently leveraged, their optical and mechanical modes can be parametrically coupled, allowing the optical excitation of vibrations. 14 In spherical shapes 9 such as our bubble,

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Section: Cavity Optomechanics On a Microfluidic Resonator With Water mentioning

confidence: 99%

“…A major application of optical resonators is in the field of sensing where microresonators were used to sense biomarkers in serum 1 and to detect viruses and nanoparticles [2][3][4] in an aqueous environment. With similar motivation and in a parallel effort, mechanical resonators were used to weigh biomolecules and cells.…”

Section: Introductionmentioning

confidence: 99%

Cavity optomechanics on a microfluidic resonator with water and viscous liquids

et al. 2013

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“…[1] In the last decade, the passive whispering gallery mode (WGM) resonators have significantly improved the sensor sensitivity, reaching down to the single mole cule level. [2][3][4] In these WGM biosensors, a tapered fiber is an important component that serves to drive the resonance mode and to guide the analyte induced wavelength shift. However, the presence of the fiber makes the sensing system complex.…”

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Microsphere Solid‐State Biolasers

Caixeiro

Fernandes

et al. 2017

Advanced Optical Materials

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Biolasers obtained from biomaterials are attracting a wealth of interest for their potential as future biosensors with enhanced sensitivity, and advanced cell tracking. Here, miniature biolasers are reported, which are formed by bovine serum albumin (BSA) protein and biosourced polysaccharides derived from land plants such as cellulose and pectin. Using a green processing route aided by simple emulsions, solid-state microspheres with diameters of 15–100 µm are fabricated and utilized as whispering gallery mode lasers with thresholds of a few µJ mm–2 and quality factors of up to 3000. Furthermore, BSA microlasers are found to be compatible with cell growth and resistant to the aqueous environment of cell culture media. This environmentally friendly and biocompatible design shows promise for future implantable biosensing devices opening a path between laser science and medicine

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“…dispersive) frequency shift of the whispering gallery modes [19] as a result of perturbations that may be present. Alternatively, a perturbation may increase the optical linewidth of the WGM by introducing more dissipation [21,22], or may change the back-scattering strength [23] and subsequent mode splitting if modal coupling is present [17,20]. The optomechanical properties of WGRs can also be used for force [24] or viscosity sensing [25].…”

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Cavity ring-up spectroscopy for dissipative and dispersive sensing in a whispering gallery mode resonator

et al. 2016

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generation [1,2], laser stabilization [3][4][5] and sensing [6,7]. The high optical quality factor (Q-factor) and relatively small mode volume of whispering gallery resonators (WGRs) render the modes very sensitive to subtle environmental changes. Until now, WGRs have been used to measure changes in a number of parameters such as refractive index [8,9], temperature [10][11][12], pressure [13,14] and stress [15,16]. Aside from parameter change detection, ultrahigh Q resonators have also been used to detect nanoparticles [17,18] and single viruses [19,20]. The mechanism behind ultrahigh sensitivity sensing in WGRs is based on a reactive (i.e. dispersive) frequency shift of the whispering gallery modes [19] as a result of perturbations that may be present. Alternatively, a perturbation may increase the optical linewidth of the WGM by introducing more dissipation [21,22], or may change the back-scattering strength [23] and subsequent mode splitting if modal coupling is present [17,20]. The optomechanical properties of WGRs can also be used for force [24] or viscosity sensing [25].Currently, in order to retrieve the dispersive, dissipative and mode splitting information, the transmission spectrum of a WGR through an externally coupled waveguide, such as a tapered optical fibre, is usually measured. Light from a tunable laser source is coupled into the tapered fibre and the transmission is monitored. Low powers are used in order to minimise thermal and nonlinear effects on the whispering gallery modes. By sweeping the laser frequency, the transmission spectrum through the fibre can be recorded. Any changes to the frequency, mode splitting or linewidth are used to monitor perturbations induced by the physical parameter that is being sensed. During measurements, the transmission spectrum represents a steady state of the coupled system; therefore, time response of the sensor [26][27][28] is related to the lifetime of the resonator which limits the scanning speed. For a WGR with Abstract In whispering gallery mode resonator sensing applications, the conventional way to detect a change in the parameter to be measured is by observing the steady-state transmission spectrum through the coupling waveguide. Alternatively, sensing based on cavity ring-up spectroscopy, i.e. CRUS, can be achieved transiently. In this work, we investigate CRUS using coupled mode equations and find analytical solutions with a large spectral broadening approximation of the input pulse. The relationships between the frequency detuning, coupling gap and ring-up peak height are determined and experimentally verified using an ultrahigh Q-factor silica microsphere. This work shows that distinctive dispersive and dissipative transient sensing can be realised by simply measuring the peak height of the CRUS signal, which may improve the data collection rate.

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Detecting single viruses and nanoparticles using whispering gallery microlasers

Cited by 602 publications

References 29 publications

Cavity optomechanics on a microfluidic resonator with water and viscous liquids

Cavity optomechanics on a microfluidic resonator with water and viscous liquids

Microsphere Solid‐State Biolasers

Cavity ring-up spectroscopy for dissipative and dispersive sensing in a whispering gallery mode resonator

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