Chaoyang Ti

Integrated tuning fork nanocavity optomechanical transducers with high fMQM product and stress-engineered frequency tuning

Cavity optomechanical systems are being widely developed for precision force and displacement measurements. For nanomechanical transducers, there is usually a trade-off between the frequency (fM) and quality factor (QM), which limits temporal resolution and sensitivity. Here, we present a monolithic cavity optomechanical transducer supporting both high fM and high QM. By replacing the common doubly clamped, Si3N4 nanobeam with a tuning fork geometry, we demonstrate devices with the fundamental fM≈29 MHz and QM≈2.2×105, corresponding to an fMQM product of 6.35×1012 Hz, comparable to the highest values previously demonstrated for room temperature operation. This high fMQM product is partly achieved by engineering the stress of the tuning fork to be 3 times the residual film stress through clamp design, which results in an increase of fM up to 1.5 times. Simulations reveal that the tuning fork design simultaneously reduces the clamping, thermoelastic dissipation, and intrinsic material damping contributions ...

Fiber based optical tweezers for simultaneous in situ force exertion and measurements in a 3D polyacrylamide gel compartment

Optical tweezers play an important role in biological applications. However, it is difficult for traditional optical tweezers based on objective lenses to work in a three-dimensional (3D) solid far away from the substrate. In this work, we develop a fiber based optical trapping system, namely inclined dual fiber optical tweezers, that can simultaneously apply and measure forces both in water and in a 3D polyacrylamide gel matrix. In addition, we demonstrate in situ, non-invasive characterization of local mechanical properties of polyacrylamide gel by measurements on an embedded bead. The fiber optical tweezers measurements agree well with those of atomic force microscopy (AFM). The inclined dual fiber optical tweezers provide a promising and versatile tool for cell mechanics study in 3D environments.

Fiber optical tweezers for simultaneous force exertion and measurements in a 3D hydrogel compartment

We developed an inclined dual fiber optical tweezers (DFOTs) for simultaneous force application and measurements in a 3D hydrogel matrix. The inclined DFOTs provide a potential solution for cell mechanics study in a three-dimensional matrix.

Objective-lens-free Fiber-based Position Detection with Nanometer Resolution in a Fiber Optical Trapping System

Position detection with high accuracy is crucial for force calibration of optical trapping systems. Most existing position detection methods require high-numerical-aperture objective lenses, which are bulky, expensive, and difficult to miniaturize. Here, we report an affordable objective-lens-free, fiber-based position detection scheme with 2 nm spatial resolution and 150 MHz bandwidth. This fiber based detection mechanism enables simultaneous trapping and force measurements in a compact fiber optical tweezers system. In addition, we achieved more reliable signal acquisition with less distortion compared with objective based position detection methods, thanks to the light guiding in optical fibers and small distance between the fiber tips and trapped particle. As a demonstration of the fiber based detection, we used the fiber optical tweezers to apply a force on a cell membrane and simultaneously measure the cellular response.

Fiber-based optical trapping for cell mechanics study and microrheology

In this work, we developed fiber based optical trapping system and explored its applications in biology and physics. We aim to replace objective lenses with optical fibers, both for optical trapping and particle position detection. Compared with objective lens based counterparts, fiber based optical trapping systems are small, low-cost, integratable, independent of objective lenses, and can work in turbid mediums. These advantages make fiber optical trapping systems ideal for applications in tightly confined spaces as well as integration with various microscopy techniques. We demonstrate the applications of fiber optical trapping systems in both single-cell mechanics and microrheology study of asphalt binders. Fiber optical trapping system is being used to study mechanical properties of viscoelastic hydrogel, as an important extra cellular matrix (ECM) material that is used to understand the force propagation on cell membranes on 2D substrates or in 3D compartments. Moreover, the fiber optical trapping system has also been demonstrated to measure the cellular response to the external mechanical stimuli. Direct measurements of cellular traction forces in 3D compartments are underway. In addition, fiber optical trapping systems are used to measure the microscale viscoelastic properties of asphalt binders, in order to improve the fundamental understanding of the relationship between mechanical and chemical properties of asphalt binders. This fundamental understanding could help targeted asphalt recycling and pavement maintenance. Fiber optical trapping systems are versatile and highly potential tools that can find applications in various areas ranging from mechanobiology to complex fluids.

Tapered optical fiber loops and helices for integrated photonic device characterization and microfluidic roller coasters

Tapered optical fibers with special geometries are desired for probing monolithic in-plane nanophotonic devices, as well as for optical trapping and manipulation. In this work, we demonstrate two special geometries of tapered optical fibers, namely fiber loops and helices. The fiber loops in this work are distinct from previous ones in terms of their superior mechanical stability and high optical quality factors in air, thanks to a post-annealing process. We experimentally measured an intrinsic optical quality factor of 32,500 and a finesse of 137 for a fiber loop. A fiber helix was used to characterize a monolithic cavity optomechanical device. Moreover, a microfluidic “roller coaster” was demonstrated, where microscale particles in water were optically trapped and transported by a fiber helix. Tapered fiber loops and helices can find various applications ranging from on-the-fly characterization of integrated photonic devices to particle manipulation and sorting in microfluidics.

High mechanical f M Q M product tuning fork cavity optomechanical transducer

We present monolithic cavity optomechanical transducers combining microdisk optical cavities with tuning fork mechanical resonators to achieve high mechanical frequency (fM ) and high quality factor (QM ), with a measured fMQM product of 6.35×1012 Hz.

Tuning Fork Cavity Optomechanical Transducers

We present on-chip Si3N4 optomechanical transducers that integrate nanomechanical tuning forks with microdisk resonators for displacement measurements. Enhanced mechanical Q relative to single cantilevers and mechanical frequency adjustment by beam stress engineering were realized.