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DTSTART;TZID=Australia/Melbourne:20210526T150000
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DESCRIPTION:This presentation focuses on structure property/relationships i
 n advanced materials\, emphasizing multifunctional systems that exhibit mu
 ltiple functionalities. Such systems are then used as building blocks for 
 the fabrication of various emerging technologies. In particular\, nanostru
 ctured materials synthesized via the bottom–up approach present an oppor
 tunity for future generation low cost manufacturing of devices [1]. We foc
 us in particular on recent developments in solar technologies that aim to 
 address the energy challenge\, including third generation photovoltaics\, 
 solar hydrogen production\, luminescent solar concentrators and other opto
 electronic devices. [2-37].\n\nReferences\n\n[1] J. Phys. Cond. Matt. 16\,
  S1373 (2004)\; [2] Adv. Mater. 22\, 1741 (2010)\; [3] J. Am. Chem. Soc. 1
 32\, 8868 (2010)\; [4] Adv. Mater. 23\, 1724 (2011)\; [5] Appl. Phys. Lett
 . 98\, 202902 (2011)\; [6] Chem. Comm. 48\, 8009 (2012)\; [7] Adv. Func. M
 ater. 22\, 3914 (2012)\; [8] Nanoscale 4\, 5588 (2012)\; [9] Nanoscale 5\,
  873 (2013)\; [10] J. Power Sources 233\, 93 (2013)\; [11] Chem. Comm. 49\
 , 5856 (2013)\; [12] J. Phys. Chem. C 117\, 14510 (2013)\; [13] Nature Pho
 t. 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\, 2331
 2 (2016)\; [20] Adv. En. Mater. 6\, 1501913 (2016)\; [21] Nanoscale 8\, 42
 17 (2016)\; [22] Adv. Sci. 3\, 1500345 (2016)\; [23] Small 11\, 5741 (2015
 )\; [24] Small 11\, 4018 (2015)\; [25] J. Mater. Chem. A 3\, 2580 (2015)\;
  [26] Nano Energy 34\, 214 (2017)\; [27] Nano Energy 35\, 92 (2017)\; [28]
  Adv. Func. Mater. 27\, 1401468 (2017)\; [29] Adv. En. Mater. 8\, 1701432 
 (2018)\; [30] Chem 3\, 229 (2017)\; [31] J. Chakrabartty et al.\, Nature P
 hot. 12\, 271 (2018)\; [32] Nano Energy 55\, 377 (2019)\; [33] Nanoscale H
 oriz. 4\, 404 (2019)\; [34] Appl. Cat. B 250\, 234 (2019)\; Adv. Func. Mat
 er. 29\, 1904501 (2019)\; [35] ACS Photonics 6\, 2479 (2019)\; [36] Appl. 
 Cat. B 264\, 118526 (2020)\; [37] Adv. Func. Mater. 30\, 1908467 (2020).\n
 \nMelbourne\, Victoria\, Australia\, Virtual: https://events.vtools.ieee.o
 rg/m/263308
LOCATION:Melbourne\, Victoria\, Australia\, Virtual: https://events.vtools.
 ieee.org/m/263308
ORGANIZER:yvisagathilagar@gmail.com
SEQUENCE:7
SUMMARY:Multifunctional materials for emerging technologies
URL;VALUE=URI:https://events.vtools.ieee.org/m/263308
X-ALT-DESC:Description: <br /><p>This presentation focuses on structure pro
 perty/relationships in advanced materials\, emphasizing multifunctional sy
 stems that exhibit multiple functionalities. Such systems are then used as
  building blocks for the fabrication of various emerging technologies. In 
 particular\, nanostructured materials synthesized via the bottom&ndash\;up
  approach present an opportunity for future generation low cost manufactur
 ing of devices [1]. We focus in particular on recent developments in solar
  technologies that aim to address the energy challenge\, including third g
 eneration photovoltaics\, solar hydrogen production\, luminescent solar co
 ncentrators and other optoelectronic devices. [2-37].</p>\n<p>&nbsp\;</p>\
 n<p><strong>References</strong></p>\n<p>[1] <em>J. Phys. Cond. Matt.</em> 
 <strong>16</strong>\, S1373 (2004)\; [2] <em>Adv. </em><em>Mater.</em> <st
 rong>22</strong>\, 1741 (2010)\; [3] <em>J. Am. </em><em>Chem. Soc.</em> <
 strong>132</strong>\, 8868 (2010)\; [4] <em>Adv. </em><em>Mater.</em> <str
 ong>23</strong>\, 1724 (2011)\; [5] <em>Appl. </em><em>Phys. </em><em>Lett
 .</em> <strong>98</strong>\, 202902 (2011)\; [6] <em>Chem. Comm. </em><str
 ong>48</strong>\, 8009 (2012)\; [7] <em>Adv. </em><em>Func. Mater. </em><s
 trong>22</strong>\, 3914 (2012)\; [8] <em>Nanoscale</em> <strong>4</strong
 >\, 5588 (2012)\; [9] <em>Nanoscale</em> <strong>5</strong>\, 873 (2013)\;
  [10] <em>J. Power Sources</em> <strong>233</strong>\, 93 (2013)\; [11] <e
 m>Chem. Comm.</em> <strong>49</strong>\, 5856 (2013)\; [12] <em>J. Phys. C
 hem. </em><em>C </em><strong>117</strong>\, 14510 (2013)\; [13] <em>Nature
  Phot. </em><strong>9</strong>\, 61 (2015)\; [14] <em>Nanoscale</em> <stro
 ng>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. </em><em>Chem. C</em> <strong>4</strong>\, 3555 (2016)\; [19] <
 em>Sci. Rep.</em> <strong>6</strong>\, 23312 (2016)\; [20] <em>Adv. En. Ma
 ter.</em> <strong>6</strong>\, 1501913 (2016)\; [21] <em>Nanoscale</em> <s
 trong>8</strong>\, 4217 (2016)\; [22] <em>Adv. Sci.</em> <strong>3</strong
 >\, 1500345 (2016)\; [23] <em>Small </em><strong>11</strong>\, 5741 (2015)
 \; [24] <em>Small</em> <strong>11</strong>\, 4018 (2015)\; [25] <em>J. Mat
 er. Chem. A</em> <strong>3</strong>\, 2580 (2015)\; [26] <em>Nano Energy</
 em> <strong>34</strong>\, 214 (2017)\; [27] <em>Nano Energy</em> <strong>3
 5</strong>\, 92 (2017)\; [28] <em>Adv. Func. Mater.</em> <strong>27</stron
 g>\, 1401468 (2017)\; [29] <em>Adv. En. Mater.</em> <strong>8</strong>\, 1
 701432 (2018)\; [30] <em>Chem</em> <strong>3</strong>\, 229 (2017)\; [31] 
 J. Chakrabartty et al.\, <em>Nature Phot.</em> <strong>12</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 Photonics</em> <stro
 ng>6</strong>\, 2479 (2019)\; [36] <em>Appl. Cat. B</em> <strong>264</stro
 ng>\, 118526 (2020)\; [37] <em>Adv. Func. Mater.</em> 30\, 1908467 (2020).
 </p>
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