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DTSTART;TZID=America/New_York:20231116T140000
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DESCRIPTION:IEEE-EDS Distinguished Lecture: Multifunctional Materials for E
 merging Solar Technologies\n\nAbstract: This presentation focuses on struc
 ture property/relationships in advanced materials\, emphasizing multifunct
 ional systems that exhibit multiple functionalities. Such systems are then
  used as building blocks for the fabrication of various emerging technolog
 ies. In particular\, nanostructured materials synthesized via the bottom
 –up approach present an opportunity for future generation low cost manuf
 acturing of devices [1]. We focus in particular on recent developments in 
 solar technologies that aim to address the energy challenge\, including th
 ird generation photovoltaics\, solar hydrogen production\, luminescent sol
 ar concentrators and other optoelectronic devices. [2-40].\n\nReferences\n
 \n[1] J. Phys. Cond. Matt. 16\, S1373 (2004)\; [2] Adv. Mater. 22\, 1741 (
 2010)\; [3] J. Am. Chem. Soc. 132\, 8868 (2010)\; [4] Adv. Mater. 23\, 172
 4 (2011)\; [5] Appl. Phys. Lett. 98\, 202902 (2011)\; [6] Chem. Comm. 48\,
  8009 (2012)\; [7] Adv. Func. Mater. 22\, 3914 (2012)\; [8] Nanoscale 4\, 
 5588 (2012)\; [9] Nanoscale 5\, 873 (2013)\; [10] J. Power Sources 233\, 9
 3 (2013)\; [11] Chem. Comm. 49\, 5856 (2013)\; [12] J. Phys. Chem. C 117\,
  14510 (2013)\; [13] Nature Phot. 9\, 61 (2015)\; [14] Nanoscale 8\, 3237 
 (2016)\; [15] Nano Energy 27\, 265 (2016)\; [16] Small 12\, 3888 (2016)\; 
 [17] Nanotechnology 27\, 215402 (2016)\; [18] J. Mater. Chem. C 4\, 3555 (
 2016)\; [19] Sci. Rep. 6\, 23312 (2016)\; [20] Adv. En. Mater. 6\, 1501913
  (2016)\; [21] Nanoscale 8\, 4217 (2016)\; [22] Adv. Sci. 3\, 1500345 (201
 6)\; [23] Small 11\, 5741 (2015)\; [24] Small 11\, 4018 (2015)\; [25] J. M
 ater. Chem. A 3\, 2580 (2015)\; [26] Nano Energy 34\, 214 (2017)\; [27] Na
 no Energy 35\, 92 (2017)\; [28] Adv. Func. Mater. 27\, 1401468 (2017)\; [2
 9] Adv. En. Mater. 8\, 1701432 (2018)\; [30] Chem 3\, 229 (2017)\; [31] Na
 ture Phot. 12\, 271 (2018)\; [32] Nano Energy 55\, 377 (2019)\; [33] Nanos
 cale Horiz. 4\, 404 (2019)\; [34] Appl. Cat. B 250\, 234 (2019)\; Adv. Fun
 c. Mater. 29\, 1904501 (2019)\; [35] ACS Photonics 6\, 2479 (2019)\; [36] 
 Appl. Cat. B 264\, 118526 (2020)\; [37] Adv. Func. Mater. 30\, 1908467 (20
 20)\; [38] J. Mater. Chem. A 8\, 20698 (2020)\; [39] Nano Energy 79\, 1054
 16 (2021)\; [40] Nano Energy 81\, 105626 (2021).\n\nSpeaker(s): Professor 
 Federico Rosei\, \n\nRoom: 3142\, Bldg: EIT\, University of Waterloo\, 200
  University Avenue West\, Waterloo\, Ontario\, Canada\, N2L3G1
LOCATION:Room: 3142\, Bldg: EIT\, University of Waterloo\, 200 University A
 venue West\, Waterloo\, Ontario\, Canada\, N2L3G1
ORGANIZER:sivoththaman@uwaterloo.ca
SEQUENCE:15
SUMMARY:Multifunctional Materials for Emerging Solar Technologies
URL;VALUE=URI:https://events.vtools.ieee.org/m/382930
X-ALT-DESC:Description: <br /><p>IEEE-EDS Distinguished Lecture: Multifunct
 ional Materials for Emerging Solar Technologies</p>\n<p>Abstract:&nbsp\;Th
 is presentation focuses on structure property/relationships in advanced ma
 terials\, emphasizing multifunctional systems that exhibit multiple functi
 onalities. Such systems are then used as building blocks for the fabricati
 on of various emerging technologies. In particular\, nanostructured materi
 als synthesized via the bottom&ndash\;up approach present an opportunity f
 or future generation low cost manufacturing of devices [1]. We focus in pa
 rticular on recent developments in solar technologies that aim to address 
 the energy challenge\, including third generation photovoltaics\, solar hy
 drogen production\, luminescent solar concentrators and other optoelectron
 ic devices. [2-40].</p>\n<p>&nbsp\;</p>\n<p>References</p>\n<p>[1] <em>J. 
 Phys. Cond. Matt.</em> <strong>16</strong>\, S1373 (2004)\; [2] <em>Adv. M
 ater.</em> <strong>22</strong>\, 1741 (2010)\; [3] <em>J. Am. Chem. Soc.</
 em> <strong>132</strong>\, 8868 (2010)\; [4] <em>Adv. Mater.</em> <strong>
 23</strong>\, 1724 (2011)\; [5] <em>Appl. Phys. Lett.</em> <strong>98</str
 ong>\, 202902 (2011)\; [6] <em>Chem. Comm. </em><strong>48</strong>\, 8009
 <em> </em>(2012)\; [7] <em>Adv. Func. Mater. </em><strong>22</strong>\, 39
 14 (2012)\; [8] <em>Nanoscale</em> <strong>4</strong>\, 5588 (2012)\; [9] 
 <em>Nanoscale</em> <strong>5</strong>\, 873 (2013)\; [10] <em>J. Power Sou
 rces</em> <strong>233</strong>\, 93 (2013)\; [11] <em>Chem. Comm.</em> <st
 rong>49</strong>\, 5856 (2013)\; [12] <em>J. Phys. Chem. C </em><strong>11
 7</strong>\, 14510<em> </em>(2013)\; [13] <em>Nature Phot. </em><strong>9<
 /strong>\, 61 (2015)\; [14] <em>Nanoscale</em> <strong>8</strong>\, 3237 (
 2016)\; [15] <em>Nano Energy </em><strong>27</strong>\, 265 (2016)\; [16] 
 <em>Small</em> <strong>12</strong>\, 3888 (2016)\; [17] <em>Nanotechnology
 </em> <strong>27</strong>\, 215402 (2016)\; [18] <em>J. Mater. Chem. C</em
 > <strong>4</strong>\, 3555 (2016)\; [19] <em>Sci. Rep.</em> <strong>6</st
 rong>\, 23312 (2016)\; [20] <em>Adv. En. Mater.</em> <strong>6</strong>\, 
 1501913 (2016)\; [21] <em>Nanoscale</em> <strong>8</strong>\, 4217 (2016)\
 ; [22] <em>Adv. Sci.</em> <strong>3</strong>\, 1500345 (2016)\; [23] <em>S
 mall </em><strong>11</strong>\, 5741 (2015)\; [24] <em>Small</em> <strong>
 11</strong>\, 4018 (2015)\; [25] <em>J. Mater. Chem. A</em> <strong>3</str
 ong>\, 2580 (2015)\; [26] <em>Nano Energy</em> <strong>34</strong>\, 214 (
 2017)\; [27] <em>Nano Energy</em> <strong>35</strong>\, 92 (2017)\; [28] <
 em>Adv. Func. Mater.</em> <strong>27</strong>\, 1401468 (2017)\; [29] <em>
 Adv. En. Mater.</em> <strong>8</strong>\, 1701432 (2018)\; [30] <em>Chem</
 em> <strong>3</strong>\, 229 (2017)\; [31] <em>Nature Phot.</em> <strong>1
 2</strong>\, 271 (2018)\; [32] <em>Nano Energy</em> <strong>55</strong>\, 
 377 (2019)\; [33] <em>Nanoscale Horiz.</em> <strong>4</strong>\, 404 (2019
 )\; [34] <em>Appl. Cat. B</em> <strong>250</strong>\, 234 (2019)\; <em>Adv
 . Func. Mater.</em> <strong>29</strong>\, 1904501 (2019)\; [35] <em>ACS Ph
 otonics</em> <strong>6</strong>\, 2479 (2019)\; [36] <em>Appl. Cat. B</em>
  <strong>264</strong>\, 118526 (2020)\; [37] <em>Adv. Func. Mater.</em> <s
 trong>30</strong>\, 1908467 (2020)\; [38] <em>J. Mater. Chem. A</em> <stro
 ng>8</strong>\, 20698 (2020)\; [39] <em>Nano Energy</em> <strong>79</stron
 g>\, 105416 (2021)\; [40] <em>Nano Energy</em> <strong>81</strong>\, 10562
 6 (2021).</p>
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