東華大學圖書館 |

A Pragmatic Approach to Nanostar Plasmonics.

Record Type:	Electronic resources : Monograph/item
Title/Author:	A Pragmatic Approach to Nanostar Plasmonics./
Author:	Tsoulos, Theodoros V.
Published:	Ann Arbor : ProQuest Dissertations & Theses, : 2019,
Description:	112 p.
Notes:	Source: Dissertations Abstracts International, Volume: 80-12, Section: B.
Contained By:	Dissertations Abstracts International80-12B.
Subject:	Computational physics. -
Online resource:	http://pqdd.sinica.edu.tw/twdaoapp/servlet/advanced?query=13422712
ISBN:	9781392221839

A Pragmatic Approach to Nanostar Plasmonics.
Tsoulos, Theodoros V.

A Pragmatic Approach to Nanostar Plasmonics. - Ann Arbor : ProQuest Dissertations & Theses, 2019 - 112 p.

Source: Dissertations Abstracts International, Volume: 80-12, Section: B.

Thesis (Ph.D.)--Rutgers The State University of New Jersey, School of Graduate Studies, 2019.

This item must not be sold to any third party vendors.

Herein we present a new modeling approach to nanostar plasmonics that treats nanostar spikes as dual cavity systems where coupled bulk and surface polaritons propagate and form standing waves. Finite element simulations of the optical behavior of gold nanostars in water reveal a new view of collective electron cloud oscillations, where localized surface plasmon resonances coexist with coherent delocalized interface waves, i.e. propagating surface plasmons. Gold nanostar spikes long enough to allow propagating polaritons, and short enough to resonate with the spherical core, serve as the substrate for the observed overlap between propagating modes and localized ones. Transverse plane plots reveal bulk polaritons coupled to surface polaritons. In light of these, we explore the mechanisms that drive the plasmonic coupling in nanostars from the single spike level to multi-spiked systems and to complex interparticle coupling ensembles. Our successful predictions in experimentally synthesized systems of increasing complexity allow us to test our method in various regimes.First, we explore changes in gold nanostar spike resonances when SiO2 shells are progressively grown onto the spikes. As the SiO2 layer thickens, the plasmonic enhancement dampens reaching a minimum due to the disrupted polaritonic coupling on the spikes. We determine a strong correlation between the nanostar morphology and its silica coating layer, the enhanced electric field, and the surface enhanced Raman scattering (SERS) signal enhancements. The modelled behavior is expressed in terms of power losses maxima and it is compared to the experimentally measured SERS signal enhancement, as both values depend on the absolute value of the electric field. A successful prediction of the trend secures the applicability of our modelling approach to systems with spatially varying and frequency dependent dielectric functions.We then calculate the shape dependent extinction coefficient, the volume, and the surface area of that real particle by introducing a detailed nanostar tomogram into our computational method and calculating its electric field under illumination with 8 different polarization orientations. In comparison to a semi-empirical, simplified model, used to calculate the same fundamental physical and optical parameters, which assumes a perfectly spherical core and identical protruding spikes, and other methods from bibliography, and based on the close agreement among the values obtained with the various approaches, we are confident that our method could be generalized for nanostars of any dimensions and arbitrary shape synthesized in solution using seed-mediated protocols.Having successfully applied our approach to structurally anisotropic particles, we propose a method for the rational design of plasmonic particles. Using the conclusions from our computational study and working in parallel with a synthetic team we establish a causal relationship between structural and plasmonic properties. By way of comparison between the observed shifts and the spectral positions of the various resonances in the experiment and the model, we use this relationship to fine tune the synthesis. Having optimized the synthesis, we focus on the resonances from the isolated single particle level studied via Ultra-Scanning Transmission Electron Microscopy and Electron Energy Loss Spectroscopy (Ultra-STEM EELS), to the highly coupled ensemble level studied via Attenuated Total Reflectance Fourier Transform Infrared Spectroscopy (FTIR-ATR). A new resonant window is covered, stretching to wavelengths in the short- wave infrared (SWIR). We have also showcased a method to determine the level of monodispersity and thus the applicability of our emerging method.In brief, we have developed a numerical approach for the detailed study of gold nanostars. Tested in anisotropic, asymmetric, and arbitrary shaped systems it proved to be a useful tool for accurate predictions of the optical and the physical properties of plasmonic particles. We utilized this approach for the development of an emerging form of a plasmonic material that covers new grounds in how far, how strong, and how narrow these particles can resonate and enhance the impinging electric field.

ISBN: 9781392221839Subjects--Topical Terms:

3343998
Computational physics.

A Pragmatic Approach to Nanostar Plasmonics.
LDR:05349nmm a2200325 4500 001 2263316
005 20200316071943.5
008 220629s2019 ||||||||||||||||| ||eng d
020 $a 9781392221839
035 $a (MiAaPQ)AAI13422712
035 $a (MiAaPQ)gsnb.rutgers:10027
035 $a AAI13422712
040 $a MiAaPQ $c MiAaPQ
100 1 $a Tsoulos, Theodoros V. $3 3540402
245 1 0 $a A Pragmatic Approach to Nanostar Plasmonics.
260 1 $a Ann Arbor : $b ProQuest Dissertations & Theses, $c 2019
300 $a 112 p.
500 $a Source: Dissertations Abstracts International, Volume: 80-12, Section: B.
500 $a Publisher info.: Dissertation/Thesis.
500 $a Advisor: Fabris, Laura.
502 $a Thesis (Ph.D.)--Rutgers The State University of New Jersey, School of Graduate Studies, 2019.
506 $a This item must not be sold to any third party vendors.
520 $a Herein we present a new modeling approach to nanostar plasmonics that treats nanostar spikes as dual cavity systems where coupled bulk and surface polaritons propagate and form standing waves. Finite element simulations of the optical behavior of gold nanostars in water reveal a new view of collective electron cloud oscillations, where localized surface plasmon resonances coexist with coherent delocalized interface waves, i.e. propagating surface plasmons. Gold nanostar spikes long enough to allow propagating polaritons, and short enough to resonate with the spherical core, serve as the substrate for the observed overlap between propagating modes and localized ones. Transverse plane plots reveal bulk polaritons coupled to surface polaritons. In light of these, we explore the mechanisms that drive the plasmonic coupling in nanostars from the single spike level to multi-spiked systems and to complex interparticle coupling ensembles. Our successful predictions in experimentally synthesized systems of increasing complexity allow us to test our method in various regimes.First, we explore changes in gold nanostar spike resonances when SiO2 shells are progressively grown onto the spikes. As the SiO2 layer thickens, the plasmonic enhancement dampens reaching a minimum due to the disrupted polaritonic coupling on the spikes. We determine a strong correlation between the nanostar morphology and its silica coating layer, the enhanced electric field, and the surface enhanced Raman scattering (SERS) signal enhancements. The modelled behavior is expressed in terms of power losses maxima and it is compared to the experimentally measured SERS signal enhancement, as both values depend on the absolute value of the electric field. A successful prediction of the trend secures the applicability of our modelling approach to systems with spatially varying and frequency dependent dielectric functions.We then calculate the shape dependent extinction coefficient, the volume, and the surface area of that real particle by introducing a detailed nanostar tomogram into our computational method and calculating its electric field under illumination with 8 different polarization orientations. In comparison to a semi-empirical, simplified model, used to calculate the same fundamental physical and optical parameters, which assumes a perfectly spherical core and identical protruding spikes, and other methods from bibliography, and based on the close agreement among the values obtained with the various approaches, we are confident that our method could be generalized for nanostars of any dimensions and arbitrary shape synthesized in solution using seed-mediated protocols.Having successfully applied our approach to structurally anisotropic particles, we propose a method for the rational design of plasmonic particles. Using the conclusions from our computational study and working in parallel with a synthetic team we establish a causal relationship between structural and plasmonic properties. By way of comparison between the observed shifts and the spectral positions of the various resonances in the experiment and the model, we use this relationship to fine tune the synthesis. Having optimized the synthesis, we focus on the resonances from the isolated single particle level studied via Ultra-Scanning Transmission Electron Microscopy and Electron Energy Loss Spectroscopy (Ultra-STEM EELS), to the highly coupled ensemble level studied via Attenuated Total Reflectance Fourier Transform Infrared Spectroscopy (FTIR-ATR). A new resonant window is covered, stretching to wavelengths in the short- wave infrared (SWIR). We have also showcased a method to determine the level of monodispersity and thus the applicability of our emerging method.In brief, we have developed a numerical approach for the detailed study of gold nanostars. Tested in anisotropic, asymmetric, and arbitrary shaped systems it proved to be a useful tool for accurate predictions of the optical and the physical properties of plasmonic particles. We utilized this approach for the development of an emerging form of a plasmonic material that covers new grounds in how far, how strong, and how narrow these particles can resonate and enhance the impinging electric field.
590 $a School code: 0190.
650 4 $a Computational physics. $3 3343998
650 4 $a Nanoscience. $3 587832
690 $a 0216
690 $a 0565
710 2 $a Rutgers The State University of New Jersey, School of Graduate Studies. $b Materials Science and Engineering. $3 3540403
773 0 $t Dissertations Abstracts International $g 80-12B.
790 $a 0190
791 $a Ph.D.
792 $a 2019
793 $a English
856 4 0 $u http://pqdd.sinica.edu.tw/twdaoapp/servlet/advanced?query=13422712