When a nanoparticle enters the microcavity it interacts with the light present by introducing a local change to the refractive index relative to the surrounding fluid. This change has two effects on the light in the cavity.
- Firstly it modifies the optical path length per round trip of the cavity so that the wavelength of the stored light shifts.
- Secondly it results in the scattering of light from the cavity, increasing the optical loss rate, which results in attenuation and spectral broadening of the light stored by the microcavity.
Both of these phenomena can be measured by scanning the cavity through resonance with a laser.
The magnitude of these effects is determined by the degree to which the nanoparticle is electrically polarised by the optical field in the cavity. The polarisability of the nanoparticle depends on its size and the ratio of its refractive index to that of the surrounding fluid. For small particles it is advantageous to measure the wavelength shift rather than attenuation. This is the key parameter used by Oxford HighQ nanoparticle analysers.
The magnitude of the shift depends on the position of the particle within the microcavity, such that the maximum value only occurs when the particle is at the location where the optical field is most intense. The position of a particle will change over time as the nanoparticles undergoes random Brownian motion in the fluid. The Oxford HighQ nanoparticle analyser measures the wavelength shift several thousand times per second to capture the changing position of the particle.
The speed of the Brownian motion is determined by the viscous drag of the fluid acting on the particle, which in turn depends on the size of the particle. The measured dynamics therefore provide information about the size of the nanoparticle. Accurate quantitative measurements are facilitated by trapping individual particles in the microcavity using the optical tweezers effect.
Find out more about our technology
Optical microcavity technology
Optical microcavities are micrometre-sized devices which confine light to a volume of space comparable with the optical wavelength.
When a nanoparticle enters a microcavity it interacts with the light present by introducing a local change to the refractive index relative to the surrounding fluid.
Our sensors are based on optical microresonators, which can amplify signals in any of the wide variety of optical methods commonly used in chemical sensing.