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DTSTART;TZID=America/New_York:20240207T100000
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DESCRIPTION:Abstract – Light-matter interactions allow adding functionali
 ties to photonic on-chip devices\, thus enabling developments in classical
  and quantum light sources\, energy harvesters and sensors. These advances
  have been facilitated by precise control in growth and fabrication techni
 ques that have opened new pathways to the design and realization of semico
 nductor devices where light emission\, trapping and guidance can be effici
 ently controlled at the nanoscale.\n\nIn this context\, I will show the im
 plementation of semiconductor quantum dots in nano-photonic devices that c
 an create simultaneously bright and pure\, triggered single-photon sources
  [1]\, critical for quantum information technology. I will then present ph
 otonic geometries for controlling light propagation and brightness in broa
 dband\, scalable devices\, based on plasmonic nanostructures [2].\n\nHybri
 d systems can allow overcoming limitations due to specific material proper
 ties and I will show how hybrid III-V/Silicon devices can be a platform fo
 r low-loss quantum light propagation [3]. I will also present a technique 
 based on the transfer of semiconductor membranes embedding quantum emitter
 s onto different host materials [4]\, for hybrid quantum photonic applicat
 ions [5].\n\nFinally\, I will discuss novel photonic designs based on bio-
 inspired aperiodic [6] and disordered photonic crystals [7]\, showing effi
 cient light confinement and optical sensing\, and I will present our recen
 t work on quantum biology\, focused on the investigation of photosynthetic
  light harvesters on a chip.\n\nCo-sponsored by: Advanced Science Research
  Center - the Graduate Center - City University of New york\n\nSpeaker(s):
  LUCA SAPIENZA\n\nASRC Auditorium\, 85 St Nicholas Terrace\, New York\, Ne
 w York\, United States\, Virtual: https://events.vtools.ieee.org/m/399744
LOCATION:ASRC Auditorium\, 85 St Nicholas Terrace\, New York\, New York\, U
 nited States\, Virtual: https://events.vtools.ieee.org/m/399744
ORGANIZER:viktoriia.rutckaia47@gc.cuny.edu
SEQUENCE:5
SUMMARY:IEEE NY JOINT MTT AP PHO & NANO CHAPTER - SEMINAR: Controlling ligh
 t down to the single-photon level with integrated quantum photonic devices
URL;VALUE=URI:https://events.vtools.ieee.org/m/399744
X-ALT-DESC:Description: <br /><p><strong>Abstract</strong>&nbsp\;&ndash\; L
 ight-matter interactions allow adding functionalities to photonic on-chip 
 devices\, thus enabling developments in classical and quantum light source
 s\, energy harvesters and sensors. These advances have been facilitated by
  precise control in growth and fabrication techniques that have opened new
  pathways to the design and realization of semiconductor devices where lig
 ht emission\, trapping and guidance can be efficiently controlled at the n
 anoscale.&nbsp\;</p>\n<p>In this context\, I will show the implementation 
 of semiconductor quantum dots in nano-photonic devices that can create sim
 ultaneously bright and pure\, triggered single-photon sources [1]\, critic
 al for quantum information technology.&nbsp\;I will then present photonic 
 geometries for controlling light propagation and brightness in broadband\,
  scalable devices\, based on plasmonic nanostructures [2].</p>\n<p>&nbsp\;
 </p>\n<p>Hybrid systems can allow overcoming limitations due to specific m
 aterial properties and I will show how hybrid III-V/Silicon devices can be
  a platform for low-loss quantum light propagation [3]. I will also presen
 t a technique based on the transfer of semiconductor membranes embedding q
 uantum emitters onto different host materials [4]\, for hybrid quantum pho
 tonic applications [5].</p>\n<p>Finally\, I will discuss novel photonic de
 signs based on bio-inspired aperiodic [6] and disordered photonic crystals
  [7]\, showing efficient light confinement and optical sensing\, and I wil
 l present our recent work on quantum biology\, focused on the investigatio
 n of photosynthetic light harvesters on a chip.</p>
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