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dc.contributor.advisorHellesø, Olav Gaute
dc.contributor.authorHasan, Md Rabiul
dc.date.accessioned2023-08-29T09:40:21Z
dc.date.available2023-08-29T09:40:21Z
dc.date.issued2023-09-14
dc.description.abstractAnalysis of biological nanoparticles in medical sciences is very promising, as it can reveal groundbreaking information about disease mechanisms, potentially leading to innovative and more effective treatment strategies. The existing methods used for analyzing biological nanoparticles come with several limitations, involving extensive sample preparation, and giving limited information about the nanoparticles. Optical tweezers combined with Raman spectroscopy is an analytical technique that has opened new possibilities for chemical analysis of biological nanoparticles. Currently used Raman optical tweezers are restricted to capturing Raman spectra from a single or a few nanoparticles and a large number of measurements are necessary to obtain valid statistics, giving low throughput analysis. Thus, development of new techniques is necessary for high-throughput chemical analysis of biological nanoparticles. The presented thesis uses numerical simulation to investigate two types of dielectric nanostructures for on-chip optical trapping and Raman spectroscopy. The aim is to find a suitable structure for high throughput analysis of multiple extracellular vesicles (EVs), a type of biological nanoparticle released from various cells. The technique relies on using the near-visible laser to trap and excite Raman scattering from the EVs. First, a low-quality factor optical nanoantenna is investigated to find the most suitable material for optical trapping of EVs. The design parameters of the nanoantennas are optimized for maximum field enhancement. The optimized designs are then used for investigating optical trapping of various nanoparticles. The temperature increase around nanoantennas with absorbing dielectric materials and corresponding thermally induced flow are also presented. The nanoantennas can be used to trap quantum dots (QDs) and polystyrene (PS) beads up to a 40 nm diameter but are not found suitable for the trapping of EVs. Then, a silicon nitride metasurface with tilted bars is numerically investigated, which supports a high-quality factor quasi-bound state in the continuum (quasi-BIC). The field enhancement is very high at the quasi-BIC resonance. It gives a significant Raman enhancement at the excitation wavelength and can be used to trap EVs with a modest input power but the size of the EVs is limited to 70 nm in diameter. The influence of trapped EVs on the quasi-BIC and trapping potential is studied. Finally, a metasurface design is presented, which consists of two parallel bars and a cylindrical disk. This gives a larger tip-to-tip gap, which can be used to trap EVs with a diameter up to 200 nm. The influence of the ellipticity of the bars on fabrication tolerances is explored and found to decrease for lower ellipticity, i.e., more circular, bars.en_US
dc.description.doctoraltypeph.d.en_US
dc.description.popularabstractIn biology and medicine, investigations of biological particles at the nanoscale have led to breakthroughs in the understanding of life processes and disease mechanisms. Currently used methods for analyzing the nanoparticles suffers from several limitations. Therefore, new methods are necessary to develop for comprehensive and detailed insights of unknown diseases. This thesis studies new methods for analyzing biological nanoparticles that mitigates some of the problems of the existing techniques. Dielectric nanoantenna and metasurface based optical tweezers are proposed, which can be used to analyze multiple nanoparticles using a laser. The numerical studies are carried out using COMSOL Multiphysics software. The study may have significant impact in the clinical applications, potentially enabling early disease detection, targeted drug delivery, and the development of novel therapeutic strategies.en_US
dc.description.sponsorshipI would like to thank Research Council of Norway and department of Physics and Technology for their financial support to carrry out this research.en_US
dc.identifier.isbn978-82-8236-533-8 (pdf)
dc.identifier.isbn978-82-8236-532-1 (trykk)
dc.identifier.urihttps://hdl.handle.net/10037/30504
dc.language.isoengen_US
dc.publisherUiT Norges arktiske universiteten_US
dc.publisherUiT The Arctic University of Norwayen_US
dc.relation.haspart<p>Paper I: Hasan, M.R. & Hellesø, Ø.G. (2021). Dielectric optical nanoantennas. <i>Nanotechnology, 32</i>(20), 202001. Also available in Munin at <a href=https://hdl.handle.net/10037/24663>https://hdl.handle.net/10037/24663</a>. <p>Paper II: Hasan, M.R. & Hellesø, Ø.G. (2023). Materials for dielectric nanotweezers in the near-visible region. <i>ACS Applied Optical Materials, 1</i>(4), 832-842. Also available at <a href=https://doi.org/10.1021/acsaom.2c00171>https://doi.org/10.1021/acsaom.2c00171</a>. <p>Paper III: Hasan, M.R. & Hellesø, Ø.G. (2023). Metasurface supporting quasi-BIC for optical trapping and Raman-spectroscopy of biological nanoparticles. <i>Optics Express, 31</i>(4), 6782-6795. Also available in Munin at <a href= https://hdl.handle.net/10037/29757> https://hdl.handle.net/10037/29757</a>. <p>Paper IV: Hasan, M.R. & Hellesø, Ø.G. Influence of ellipticity on quasi-BIC in metasurface with parallel bars and a disk. (Submitted manuscript).en_US
dc.rights.accessRightsopenAccessen_US
dc.rights.holderCopyright 2023 The Author(s)
dc.rights.urihttps://creativecommons.org/licenses/by-nc-sa/4.0en_US
dc.rightsAttribution-NonCommercial-ShareAlike 4.0 International (CC BY-NC-SA 4.0)en_US
dc.subjectVDP::Mathematics and natural science: 400::Physics: 430::Electromagnetism, acoustics, optics: 434en_US
dc.subjectVDP::Matematikk og Naturvitenskap: 400::Fysikk: 430::Elektromagnetisme, akustikk, optikk: 434en_US
dc.titleDielectric nanoantennas and metasurfaces for optical trappingen_US
dc.typeDoctoral thesisen_US
dc.typeDoktorgradsavhandlingen_US


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