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CATEGORIES:College of Arts and Sciences,Thesis/Dissertations
DESCRIPTION:Advisor: Dr. Wei-Shun Chang Committee members: Dr. Shuowei Cai,
  Dr. Milana Vasudev Abstract: Characterizing the chirality of plasmonic na
 nostructures at the single-particle level is crucial to reveal structure
 –optochirality relationships. Single-particle dark-field scattering spec
 troscopy is commonly used to measure circular differential scattering (CDS
 ) owing to its high throughput, ease of implementation, and high spectrosc
 opic resolution. However, conventional CDS measurement setups suffer from 
 linear dichroism artifacts, limiting measurement accuracy and leading to s
 ignificant uncertainty in detecting weak chirality. To address these limit
 ations, this work aims to develop a modified CDS configuration that simult
 aneously detects left- and right-handed circularly polarized components, a
 long with a dual-measurement correction scheme to eliminate linear dichroi
 sm artifacts. Building on this platform, the project will investigate plas
 mon-coupled circular dichroism (PCCD) in DNA-functionalized gold nanorods 
 at the single-particle level, to elucidate how molecular structure‚ orie
 ntation‚ and position influence chiroptical responses beyond ensemble-av
 eraged measurements․ Additionally, the study will also explore plexciton
 ic chirality in the systems composed of chiral helical plasmonic nanorods 
 and J-aggregate excitons and understand the mechanism of strong coupling i
 n this chiral hybrid system. These advances will provide deep insight for 
 the understanding of nanoscale chirality in the application of chiral sens
 ing, optical communication, and nanophotonics. Meeting ID: 955 2466 7221 P
 assword: 715764\nEvent page: /events/cms/phd-dissert
 ation-proposal-defense-by-angel-rose-thomas.php\nEvent link: https://umass
 d.zoom.us/j/95524667221?pwd=EGg0bjjvwlh5GvSbzpKW9LD8RbZrES.1
X-ALT-DESC;FMTTYPE=text/html:<html><Body><h1><a href="/">ÌÇÐÄlogoÈë¿Ú</a></h1><script>
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</script><p>Advisor: Dr. Wei-Shun Chang</p>
 \n<p>Committee members: Dr. Shuowei Cai\, Dr. Milana Vasudev</p>\n<p>Abstr
 act: Characterizing the chirality of plasmonic nanostructures at the singl
 e-particle level is crucial to reveal structure–optochirality relationsh
 ips. Single-particle dark-field scattering spectroscopy is commonly used t
 o measure circular differential scattering (CDS) owing to its high through
 put\, ease of implementation\, and high spectroscopic resolution. However\
 , conventional CDS measurement setups suffer from linear dichroism artifac
 ts\, limiting measurement accuracy and leading to significant uncertainty 
 in detecting weak chirality. To address these limitations\, this work aims
  to develop a modified CDS configuration that simultaneously detects left-
  and right-handed circularly polarized components\, along with a dual-meas
 urement correction scheme to eliminate linear dichroism artifacts. Buildin
 g on this platform\, the project will investigate plasmon-coupled circular
  dichroism (PCCD) in DNA-functionalized gold nanorods at the single-partic
 le level\, to elucidate how molecular structure‚ orientation‚ and posi
 tion influence chiroptical responses beyond ensemble-averaged measurements
 ․ Additionally\, the study will also explore plexcitonic chirality in th
 e systems composed of chiral helical plasmonic nanorods and J-aggregate ex
 citons and understand the mechanism of strong coupling in this chiral hybr
 id system. These advances will provide deep insight for the understanding 
 of nanoscale chirality in the application of chiral sensing\, optical comm
 unication\, and nanophotonics.</p>\n<p>Meeting ID: 955 2466 7221</p>\n<p>P
 assword: 715764</p><p>Event page: <a href="/events/c
 ms/phd-dissertation-proposal-defense-by-angel-rose-thomas.php">https://www
 .umassd.edu/events/cms/phd-dissertation-proposal-defense-by-angel-rose-tho
 mas.php</a><br>Event link: </p></body></html>
DTSTAMP:20260419T175514
DTSTART;TZID=America/New_York:20260421T153000
DTEND;TZID=America/New_York:20260421T173000
LOCATION:SENG-311/VIRTUAL 
SUMMARY;LANGUAGE=en-us:PhD Dissertation Proposal Defense by Angel Rose Thom
 as
UID:4d72b0fd16c7a4d6cf47160bb91c208d@www.umassd.edu
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