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PRODID:IEEE vTools.Events//EN
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DTSTART:20230312T030000
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DTSTART:20231105T010000
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BEGIN:VEVENT
DTSTAMP:20230604T133810Z
UID:E7D7F691-CAD1-4261-97A1-6409DA0DEDC4
DTSTART;TZID=America/New_York:20230601T100000
DTEND;TZID=America/New_York:20230601T113000
DESCRIPTION:A new modeling formalism to compute the time-dependent behavior
  of combined electromagnetic (EM) and quantum mechanical (QM) systems is p
 roposed. The method is geared towards highly multiscale geometries\, which
  is vital for the future design of nanoelectronic devices. The validity of
  the proposed formalism is thoroughly discussed and its applicability is p
 roven through several numerical experiments\, including a single-particle 
 Maxwell-Schrödinger (MS) system as well as a many-particle Maxwell-Kohn-S
 ham (MKS) system. These experiments confirm that the novel method drastica
 lly decreases the computation time while retaining the accuracy\, leading 
 to efficient and accurate simulations of light-matter interactions in mult
 iscale nanoelectronic devices.\n\nSpeaker(s): Dries VandeGinste\, \n\nVirt
 ual: https://events.vtools.ieee.org/m/362736
LOCATION:Virtual: https://events.vtools.ieee.org/m/362736
ORGANIZER:costas.sarris@utoronto.ca
SEQUENCE:3
SUMMARY:A Hybrid EM/QM Framework Based on the ADHIE-FDTD Method for the Mod
 eling of Nanowires (Dries VandeGinste\, Ghent)
URL;VALUE=URI:https://events.vtools.ieee.org/m/362736
X-ALT-DESC:Description: <br /><p>A new modeling formalism to compute the ti
 me-dependent behavior of combined electromagnetic (EM) and quantum mechani
 cal (QM) systems is proposed. The method is geared towards highly multisca
 le geometries\, which is vital for the future design of nanoelectronic dev
 ices. The validity of the proposed formalism is thoroughly discussed and i
 ts applicability is proven through several numerical experiments\, includi
 ng a single-particle Maxwell-Schr&ouml\;dinger (MS) system as well as a ma
 ny-particle Maxwell-Kohn-Sham (MKS) system. These experiments confirm that
  the novel method drastically decreases the computation time while retaini
 ng the accuracy\, leading to efficient and accurate simulations of light-m
 atter interactions in multiscale nanoelectronic devices.&nbsp\;</p>
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