All-optical manipulation of photonic membranes

Kirkpatrick, Blair Connell

January 2017

Optical tweezers have allowed us to harness the momentum of light to trap, move, and manipulate microscopic particles with Angstrom-level precision. Position and force feedback systems grant us the ability to feel the microscopic world. As a tool, optical tweezers have allowed us to study a variety of biological systems, from the mechanical properties of red blood cells to the quantised motion of motor-molecules such as kinesin. They have been applied, with similar impact, to the manipulation of gases, atoms, and Bose-Einstein condensates. There are, however, limits to their applicability. Historically speaking, optical tweezers have only been used to trap relatively simple structures such as spheres or cylinders. This thesis is concerned with the development of a fabricational and optical manipulation protocol that allows holographical optical tweezers to trap photonic membranes. Photonic membranes are thin, flexible membranes, that are capable of supporting nanoplasmonic features. These features can be patterned to function as metamaterials, granting the photonic membrane the ability to function as almost any optical device. It is highly desirable to take advantage of these tools in a microfluidic environment, however, their extreme aspect ratios mean that they are not traditionally compatible with the primary technology of microfluidic manipulation: optical tweezers. In line with recent developments in optical manipulation, an holistic approach to optical trapping is used to overcome these limitations. Full six-degree-of-freedom control over a photonic membrane is demonstrated through the use of holographical optical tweezers. Furthermore, a photonic membrane (PM)-based surface-enhanced Raman spectroscopy sensor is presented which is capable of detecting rhodamine dye from a topologically undulating sample. This work moves towards marrying these technologies such that photonic membranes, designed for bespoke applications, can be readily deployed into a microfluidic environment. Extending the range of tools available in the microfluidic setting helps pave the way toward the next set of advances in the field of optical manipulation.

621.36

Optimization and Parametric Characterization of a Hydrodynamic Microvortex Chip for Single Cell Rotation

January 2013

abstract: Volumetric cell imaging using 3D optical Computed Tomography (cell CT) is advantageous for identification and characterization of cancer cells. Many diseases arise from genomic changes, some of which are manifest at the cellular level in cytostructural and protein expression (functional) features which can be resolved, captured and quantified in 3D far more sensitively and specifically than in traditional 2D microscopy. Live single cells were rotated about an axis perpendicular to the optical axis to facilitate data acquisition for functional live cell CT imaging. The goal of this thesis research was to optimize and characterize the microvortex rotation chip. Initial efforts concentrated on optimizing the microfabrication process in terms of time (6-8 hours v/s 12-16 hours), yield (100% v/s 40-60%) and ease of repeatability. This was done using a tilted exposure lithography technique, as opposed to the backside diffuser photolithography (BDPL) method used previously (Myers 2012) (Chang and Yoon 2004). The fabrication parameters for the earlier BDPL technique were also optimized so as to improve its reliability. A new, PDMS to PDMS demolding process (soft lithography) was implemented, greatly improving flexibility in terms of demolding and improving the yield to 100%, up from 20-40%. A new pump and flow sensor assembly was specified, tested, procured and set up, allowing for both pressure-control and flow-control (feedback-control) modes; all the while retaining the best features of a previous, purpose-built pump assembly. Pilot experiments were performed to obtain the flow rate regime required for cell rotation. These experiments also allowed for the determination of optimal trapezoidal neck widths (opening to the main flow channel) to be used for cell rotation characterization. The optimal optical trap forces were experimentally estimated in order to minimize the required optical power incident on the cell. Finally, the relationships between (main channel) flow rates and cell rotation rates were quantified for different trapezoidal chamber dimensions, and at predetermined constant values of laser trapping strengths, allowing for parametric characterization of the system. / Dissertation/Thesis / Demonstration of process flow in the microvortex chip / Cell rotation in a 50 microns wide (at the neck) trapezoidal chamber,at a flow rate of 95 microliters/min at approximately 0.25 rev/s / Cell rotation in a 70 microns wide (at the neck) trapezoidal chamber,at a flow rate of 7 microliters/min at approximately 0.125 rev/s / M.S. Bioengineering 2013

Biomedical engineering

Cell rotation

Microfabrication

Microvortex

Optical tweezers

Optimization

A study of microviscosity in liquid crystals using laser tweezers

Sanders, Jennifer Louise

January 2012

No description available.

530.429

Feedback Control of Optically Trapped Nanoparticles and its Applications

Jaehoon Bang (8795519)

04 May 2020

<div>In the 1970's, Arthur Ashkin developed a remarkable system called the ``optical tweezer'' which utilizes the radiation pressure of light to manipulate particles. Because of its non-invasive nature and controllability, optical tweezers have been widely adopted in biology, chemistry and physics. In this dissertation, two applications related to optical tweezers will be discussed. The first application is about the demonstration of multiple feedback controlled optical tweezers which let us conduct novel experiments which have not been performed before. For the second application, levitation of a silica nanodumbbell and cooling its motion in five degrees of freedom is executed.</div><div><br></div><div>To be more specific, the first chapter of the thesis focuses on an experiment using the feedback controlled optical tweezers in water. A well-known thought experiment called ``Feynman's ratchet and pawl'' is experimentally demonstrated. Feynman’s ratchet is a microscopic heat engine which can rectify the random thermal fluctuation of molecules to harness useful work. After Feynman proposed this system in the 1960’s, it has drawn a lot of interest. In this dissertation, we demonstrate a solvable model of Feynman’s ratchet using a silica nanoparticle inside a feedback controlled one dimensional optical trap. The idea and techniques to realize two separate thermal reservoirs and to keep them in contact with the ratchet is discussed in detail. Also, both experiment and simulation about the characteristics of our system as a heat engine are fully explored.</div><div><br></div><div>In the latter part of the dissertation, trapping silica nanodumbbell in vacuum and cooling its motion in five degrees of freedom is discussed. A levitated nanoparticle in vacuum is an extraordinary optomechanical system with an exceptionally high mechanical quality factor. Therefore, levitated particles are often utilized as a sensor in various research. Different from a levitated single nanosphere, which is only sensitive to force, a levitated nanodumbbell is sensitive to both force and torque. This is due to the asymmetry of the particle resulting it to have three rotational degrees of freedoms as well as three translational degrees of freedoms. In this dissertation, creating and levitating a silica nanodumbbell will be demonstrated. Active feedback cooling also known as cold damping will be employed to stabilize and cool the two torsional degrees of freedom of the particle along with the three center of mass DOF in vacuum. Additionally, both computational and experimental analysis is conducted on a levitated nanodumbbell which we call rotation-coupled torsional motion. The complex torsional motion can be fully explained with the effects of both thermal nonlinearity and rotational coupling. The new findings and knowledge of a levitated non-spherical particles leads us one step further towards levitated optomechanics with more complex particles.</div>

Classical and Physical Optics

Optical tweezers

Feedback control

Optomechanics

Stochastic thermodynamics

Nanostructured metals for enhanced light-matter interaction with nanoscale materials: design, sensing and single photon emitters

Sharifi, Zohreh

16 May 2022

Plasmonics have been used to enhance the interaction of light with metallic nanostructures and lanthanide-doped upconversion nanocrystals. This enhancement can be achieved by using specific structures, materials, and plasmonic resonators at the emission and absorption wavelengths of the particles. This dissertation is based on four projects, which are mainly about the interaction of light and matter in metallic nanostructures and the up-conversion of nanocrystals using plasmonic resonators. In metal-insulator-metal systems, the cavity's resonant length is determined by the plasmon wavevector and the phase of reflection from the end faces. In general, the resonance length is not a simple multiple of the half-wavelength due to the significant reflection phase. As a result, in order to have a better understanding of MIM cavity resonances, the reflection phase must be calculated correctly. In the first project, the reflection phase obtained by SPPs upon reflection off the slit end-faces is calculated analytically using a simple mode matching model for real metals showing both dispersion and loss. The technique is similar to previous works, with the exception that we use the unconjugated version of the orthogonality relation. The results show good agreement with the experimental data. By having a strong grasp of the SPP dispersion, this technique aids in the design of plasmonic devices for operation at a specific wavelength. Single-photon sources are optical sources capable of emitting a single photon. A single lanthanide ion within a plasmonic nano structure with a large emission enhancement is one technique to generate a single-photon source at 1550 nm, which is a low-loss band used in fibre optics. In the second project, plasmonic double nanohole resonators are fabricated using colloidal lithography. These structures have been used to enhance the emission from low-concentration erbium emitters. The results indicate that different levels of emissions exist based on the amount of Er contained inside the nanocrystals. These findings would be an excellent starting point for developing a single-photon source operating at a 1550 nm wavelength employing erbium. Because not only can it increase the emission rate from erbium emitters, but it also helps to find and isolate a single emitter, which gives a stable single photon source. Because the surface plasmon resonance is exponentially coupled to the surface, it exhibits excellent sensitivity to changes in the refractive index near the surface. This is the underlying principle of commercially available surface plasmon resonance biosensors. Due to the wide range of applications in water quality testing and biosensing, it is critical to developing highly sensitive sensors that are compatible with commercial sensors. In the third project, we develop a design for SRSP sensing using a rectangular stripe grating and a 10 nm thick gold film. The 10 nm gold layer is sufficiently thick to enable continuous films to be formed using standard deposition procedures. We demonstrate that by employing rigorous coupled-wave analysis, the surface sensitivity of these films to an adlayer is increased by 3.3 times in angle units and the resolution is increased by fourfold while working at the commercial SPR system wavelength of 760 nm. Before trapping a particle in double nanohole apertures, we must first locate the double nanohole on the sample (gold on glass with apertures) and compare the scanning electron microscopy images with the image on the camera in the optical setup using certain markers. In the fourth project, to make DNH aperture trapping easier, we provide a polarization and transmission dependency approach for localizing and orienting DNHs on a substrate. This method provides a time and cost-effective way to ease the experimental process. This technique may also be used to localize different aperture clusters and single holes. / Graduate

Plasmonic

Nanostructures

Slit in a real metal

Optical tweezers

Single photon sources

SYNTHESIS OF ULTRAHIGH MOLECULAR WEIGHT POLY(METHYL METHACRYLATE) FOR SINGLE POLYMER STUDIES

Ren, Kehao

28 April 2021

No description available.

Chemistry

Regulation Analysis of DNA G-quadruplex and i-Motif bySingle-Molecule Laser Tweezers

Cui, Yunxi

30 November 2016

No description available.

Analytical Chemistry

Biochemistry

Laser tweezers

Single molecule

DNA

Microfabricated tweezers with a large gripping force and a large range of motion

Chu, Wen-Hwa Martin

January 1994

No description available.

Microfabricated tweezers

large gripping force

large range of motion

Solution-based analysis of individual perovskite quantum dots and coupled quantum dot dimers using nanoplasmonic tweezers

Zhang, Hao

16 September 2022

Cesium lead halide perovskite quantum dots (PQDs) provide an extraordinary solution-based method to fabricate high-performance solar cells, luminescent lightemitting devices, highly coherent single-photon quantum sources, and studying quantum mechanisms for quantum computing technologies. In these applications, characterizing heterogeneity and observing coupling between dots is critical. In this thesis, we use double-nanohole (DNH) optical tweezers to realize single trapping for PQDs in solution. We can estimate the size of an individual dot by studying thermal fluctuations and correlate it to emission energy shifts from quantum confinement. Based on single trapping experiment, we also use the same setup to capture a second dot by using the DNH tweezer and observe a systematic red-shift of 1.1 ± 0.6 meV in the emission wavelength upon multiple repeated measurements. Theoretical analysis shows that the experiment results are consistent with Förster resonant energy transfer (FRET), which has been proposed to obtain entanglement between colloidal quantum dots for quantum information applications. The value of the FRET is quite large when compared with the confined quantum dots and it is exciting for FRET to generate entanglement for quantum information processing applications (e.g. quantum logic gates). In the thesis, we have proved that our method allows for in-situ sizing of individual PQDs for the first time, which is relevant for improving the growth process and does not require expensive techniques. It also enables future work to search and select two dots that are nominally identical. Optical trapping with DNHs fabricated using colloidal lithography can be used to control PQD growth in-situ and enables further studies of the coupling of quantum dots at a small distance with quantum information applications. / Graduate

Nano tweezers

DNH

perovskite quantum dots

resonant energy transfer

Molecular Population Dynamics of DNA Tetraplexes using Magneto-Optical Tweezers

Selvam, Sangeetha

22 February 2018

No description available.

Analytical Chemistry

Biochemistry

Biophysics

Chemistry

DNA Supercoil

single-molecule

optical tweezers

magneto-optical tweezers

G-quadruplex

i-motif

torsionally constrained DNA