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DTSTAMP:20230729T004817Z
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DTSTART;TZID=America/Los_Angeles:20230728T120000
DTEND;TZID=America/Los_Angeles:20230728T130000
DESCRIPTION:The Electron Devices Society Santa Clara Valley/San Francisco j
 oint Chapter is hosting Prof. Eric Pop. The title of the lecture is ‘Wha
 t Are 2D Materials Good For?’\n\nWhen: Friday\, July 28\, 2023 – 12 No
 on to 1 pm (PDT)\n\nWhere: This is an online event and attendees can parti
 cipate via Zoom.\n\nRegistration Link: [Here](https://bit.ly/42HxqXv)\n\nC
 ontact: hiuyung.wong at ieee.org\n\nSpeaker: Prof. Eric Pop\n\nAbstract:\n
 \nThis talk will present my (biased!) perspective of what two-dimensional 
 (2D) materials could be good for. For example\, they could be good for app
 lications where their ultrathin nature gives them distinct advantages\, su
 ch as flexible electronics [1] or light-weight solar cells [2]. They may n
 ot be good where conventional materials work sufficiently well\, like tran
 sistors thicker than a few nanometers. I will focus on 2D materials for 3D
  heterogeneous integration of electronics\, which presents major advantage
 s for energy-efficient computing [3]. Here\, 2D materials could be monolay
 er transistors with ultralow leakage [4] (due to larger band gaps than sil
 icon)\, used to access high-density memory [5]. Recent results from our gr
 oup [6\,7] and others [8] have shown monolayer transistors with good perfo
 rmance\, which cannot be achieved with sub-nanometer thin conventional sem
 iconductors\, and the 2D performance could be further boosted by strain [9
 ]. I will also describe some unconventional applications\, using 2D materi
 als as thermal insulators [10]\, heat spreaders [11]\, and thermal transis
 tors [12]. These could enable control of heat in “thermal circuits” an
 alogous with electrical circuits. Combined\, these studies reveal fundamen
 tal limits and some unusual applications of 2D materials\, which take adva
 ntage of their unique properties.\n\nRefs: [1] A. Daus et al.\, Nat. Elec.
  4\, 495 (2021). [2] K. Nassiri Nazif\, et al.\, Nat. Comm. 12\, 7034 (202
 1). [3] M. Aly et al.\, Computer 48\, 24 (2015). [4] C. Bailey et al.\, EM
 C (2019). [5] A. Khan et al. Science 373\, 1243 (2021). [6] C. English et 
 al.\, IEDM\, Dec 2016. [7] C. McClellan et al. ACS Nano 15\, 1587 (2021). 
 [8] S. Das et al.\, Nat. Elec. 4\, 786 (2021). [9] I. Datye et al.\, Nano 
 Lett. 22\, 8052 (2022). [10] S. Vaziri et al.\, Science Adv. 5\, eaax1325 
 (2019). [11] C. Koroglu & E. Pop\, IEEE Elec. Dev. Lett. 44\, 496 (2023). 
 [12] M. Chen et al.\, 2D Mater. 8\, 035055 (2021).\n\n.\n\nSpeaker Bio:\n\
 nEric Pop is the Pease-Ye Professor of Electrical Engineering (EE) and Mat
 erials Science & Engineering (by courtesy) at Stanford\, where he leads th
 e SystemX Heterogeneous Integration focus area and the EE Culture\, Equity
 \, and Inclusion committee. His research interests include nanoelectronics
 \, data storage\, and energy. Before Stanford\, he spent several years on 
 the faculty of UIUC\, and in industry at Intel and IBM. He received his Ph
 D in EE from Stanford (2005) and three degrees from MIT in EE and Physics.
  His awards include the PECASE from the White House\, and Young Investigat
 or Awards from the Navy\, Air Force\, NSF CAREER\, and DARPA. He is an APS
  and IEEE Fellow\, an Editor of 2D Materials\, and a Clarivate Highly Cite
 d Researcher. In his spare time he enjoys snowboarding and tennis\, and in
  a past life he was a college radio DJ at KZSU 90.1. More information abou
 t the Pop Lab is available at http://poplab.stanford.edu and on Twitter [@
 profericpop](https://twitter.com/profericpop)..\n\nSpeaker(s): Prof. Eric 
 Pop\n\nAgenda: \nThe Electron Devices Society Santa Clara Valley/San Franc
 isco joint Chapter is hosting Prof. Eric Pop. The title of the lecture is 
 ‘What Are 2D Materials Good For?’\n\nWhen: Friday\, July 28\, 2023 –
  12 Noon to 1 pm (PDT)\n\nWhere: This is an online event and attendees can
  participate via Zoom.\n\nRegistration Link: [Here](https://bit.ly/42HxqXv
 )\n\nContact: hiuyung.wong at ieee.org\n\nSpeaker: Prof. Eric Pop\n\nAbstr
 act:\n\nThis talk will present my (biased!) perspective of what two-dimens
 ional (2D) materials could be good for. For example\, they could be good f
 or applications where their ultrathin nature gives them distinct advantage
 s\, such as flexible electronics [1] or light-weight solar cells [2]. They
  may not be good where conventional materials work sufficiently well\, lik
 e transistors thicker than a few nanometers. I will focus on 2D materials 
 for 3D heterogeneous integration of electronics\, which presents major adv
 antages for energy-efficient computing [3]. Here\, 2D materials could be m
 onolayer transistors with ultralow leakage [4] (due to larger band gaps th
 an silicon)\, used to access high-density memory [5]. Recent results from 
 our group [6\,7] and others [8] have shown monolayer transistors with good
  performance\, which cannot be achieved with sub-nanometer thin convention
 al semiconductors\, and the 2D performance could be further boosted by str
 ain [9]. I will also describe some unconventional applications\, using 2D 
 materials as thermal insulators [10]\, heat spreaders [11]\, and thermal t
 ransistors [12]. These could enable control of heat in “thermal circuits
 ” analogous with electrical circuits. Combined\, these studies reveal fu
 ndamental limits and some unusual applications of 2D materials\, which tak
 e advantage of their unique properties.\n\nRefs: [1] A. Daus et al.\, Nat.
  Elec. 4\, 495 (2021). [2] K. Nassiri Nazif\, et al.\, Nat. Comm. 12\, 703
 4 (2021). [3] M. Aly et al.\, Computer 48\, 24 (2015). [4] C. Bailey et al
 .\, EMC (2019). [5] A. Khan et al. Science 373\, 1243 (2021). [6] C. Engli
 sh et al.\, IEDM\, Dec 2016. [7] C. McClellan et al. ACS Nano 15\, 1587 (2
 021). [8] S. Das et al.\, Nat. Elec. 4\, 786 (2021). [9] I. Datye et al.\,
  Nano Lett. 22\, 8052 (2022). [10] S. Vaziri et al.\, Science Adv. 5\, eaa
 x1325 (2019). [11] C. Koroglu & E. Pop\, IEEE Elec. Dev. Lett. 44\, 496 (2
 023). [12] M. Chen et al.\, 2D Mater. 8\, 035055 (2021).\n\n.\n\nSpeaker B
 io:\n\nEric Pop is the Pease-Ye Professor of Electrical Engineering (EE) a
 nd Materials Science & Engineering (by courtesy) at Stanford\, where he le
 ads the SystemX Heterogeneous Integration focus area and the EE Culture\, 
 Equity\, and Inclusion committee. His research interests include nanoelect
 ronics\, data storage\, and energy. Before Stanford\, he spent several yea
 rs on the faculty of UIUC\, and in industry at Intel and IBM. He received 
 his PhD in EE from Stanford (2005) and three degrees from MIT in EE and Ph
 ysics. His awards include the PECASE from the White House\, and Young Inve
 stigator Awards from the Navy\, Air Force\, NSF CAREER\, and DARPA. He is 
 an APS and IEEE Fellow\, an Editor of 2D Materials\, and a Clarivate Highl
 y Cited Researcher. In his spare time he enjoys snowboarding and tennis\, 
 and in a past life he was a college radio DJ at KZSU 90.1. More informatio
 n about the Pop Lab is available at http://poplab.stanford.edu and on Twit
 ter [@profericpop](https://twitter.com/profericpop)..\n\nVirtual: https://
 events.vtools.ieee.org/m/364501
LOCATION:Virtual: https://events.vtools.ieee.org/m/364501
ORGANIZER:hiuyung.wong@ieee.org 
SEQUENCE:47
SUMMARY:EDS Event: What Are 2D Materials Good For?
URL;VALUE=URI:https://events.vtools.ieee.org/m/364501
X-ALT-DESC:Description: <br /><div>\n<p>The Electron Devices Society Santa 
 Clara Valley/San Francisco joint Chapter is hosting Prof. Eric Pop. The ti
 tle of the lecture is &lsquo\;What Are 2D Materials Good For?&rsquo\;</p>\
 n<h3>When: Friday\, July 28\, 2023 &ndash\; 12 Noon to 1 pm (PDT)</h3>\n<h
 3>Where: This is an online event and attendees can participate via Zoom.</
 h3>\n<h3>Registration Link: <a href="https://bit.ly/42HxqXv" target="_blan
 k" rel="noopener">Here</a></h3>\n<h4>Contact: <span class="gI"><span class
 ="qu" role="gridcell"><span class="go">hiuyung.wong at ieee.org</span></sp
 an></span></h4>\n</div>\n<h2>&nbsp\;</h2>\n<div>\n<h2><strong>Speaker: Pro
 f. Eric Pop<br /></strong></h2>\n<h3>Abstract:</h3>\n<p>This talk will pre
 sent my (biased!) perspective of what two-dimensional (2D) materials could
  be good for. For example\, they could be good for applications where thei
 r ultrathin nature gives them distinct advantages\, such as flexible elect
 ronics [1] or light-weight solar cells [2]. They may not be good where con
 ventional materials work sufficiently well\, like transistors thicker than
  a few nanometers. I will focus on 2D materials for 3D heterogeneous integ
 ration of electronics\, which presents major advantages for energy-efficie
 nt computing [3]. Here\, 2D materials could be monolayer transistors with 
 ultralow leakage [4] (due to larger band gaps than silicon)\, used to acce
 ss high-density memory [5]. Recent results from our group [6\,7] and other
 s [8] have shown monolayer transistors with good performance\, which canno
 t be achieved with sub-nanometer thin conventional semiconductors\, and th
 e 2D performance could be further boosted by strain [9]. I will also descr
 ibe some unconventional applications\, using 2D materials as thermal insul
 ators [10]\, heat spreaders [11]\, and thermal transistors [12]. These cou
 ld enable control of heat in &ldquo\;thermal circuits&rdquo\; analogous wi
 th electrical circuits. Combined\, these studies reveal fundamental limits
  and some unusual applications of 2D materials\, which take advantage of t
 heir unique properties.</p>\n<p>Refs: [1] A. Daus et al.\, Nat. Elec. 4\, 
 495 (2021). [2] K. Nassiri Nazif\, et al.\, Nat. Comm. 12\, 7034 (2021). [
 3] M. Aly et al.\, Computer 48\, 24 (2015). [4] C. Bailey et al.\, EMC (20
 19). [5] A. Khan et al. Science 373\, 1243 (2021). [6] C. English et al.\,
  IEDM\, Dec 2016. [7] C. McClellan et al. ACS Nano 15\, 1587 (2021). [8] S
 . Das et al.\, Nat. Elec. 4\, 786 (2021). [9] I. Datye et al.\, Nano Lett.
  22\, 8052 (2022). [10] S. Vaziri et al.\, Science Adv. 5\, eaax1325 (2019
 ). [11] C. Koroglu &amp\; E. Pop\, IEEE Elec. Dev. Lett. 44\, 496 (2023). 
 [12] M. Chen et al.\, 2D Mater. 8\, 035055 (2021).</p>\n<p>.</p>\n<h3>Spea
 ker Bio:</h3>\n<p>Eric Pop is the Pease-Ye Professor of Electrical Enginee
 ring (EE) and Materials Science &amp\; Engineering (by courtesy) at Stanfo
 rd\, where he leads the SystemX Heterogeneous Integration focus area and t
 he EE Culture\, Equity\, and Inclusion committee. His research interests i
 nclude nanoelectronics\, data storage\, and energy. Before Stanford\, he s
 pent several years on the faculty of UIUC\, and in industry at Intel and I
 BM. He received his PhD in EE from Stanford (2005) and three degrees from 
 MIT in EE and Physics. His awards include the PECASE from the White House\
 , and Young Investigator Awards from the Navy\, Air Force\, NSF CAREER\, a
 nd DARPA. He is an APS and IEEE Fellow\, an Editor of <em>2D Materials</em
 >\, and a Clarivate Highly Cited Researcher. In his spare time he enjoys s
 nowboarding and tennis\, and in a past life he was a college radio DJ at K
 ZSU 90.1. More information about the Pop Lab is available at <a href="http
 ://poplab.stanford.edu">http://poplab.stanford.edu</a> and on Twitter <a h
 ref="https://twitter.com/profericpop">@profericpop</a>..</p>\n</div><br />
 <br />Agenda: <br /><div>\n<p>The Electron Devices Society Santa Clara Val
 ley/San Francisco joint Chapter is hosting Prof. Eric Pop. The title of th
 e lecture is &lsquo\;What Are 2D Materials Good For?&rsquo\;</p>\n<h3>When
 : Friday\, July 28\, 2023 &ndash\; 12 Noon to 1 pm (PDT)</h3>\n<h3>Where: 
 This is an online event and attendees can participate via Zoom.</h3>\n<h3>
 Registration Link: <a href="https://bit.ly/42HxqXv" target="_blank" rel="n
 oopener">Here</a></h3>\n<h4>Contact: <span class="gI"><span class="qu" rol
 e="gridcell"><span class="go">hiuyung.wong at ieee.org</span></span></span
 ></h4>\n</div>\n<h2>&nbsp\;</h2>\n<div>\n<h2><strong>Speaker: Prof. Eric P
 op<br /></strong></h2>\n<h3>Abstract:</h3>\n<p>This talk will present my (
 biased!) perspective of what two-dimensional (2D) materials could be good 
 for. For example\, they could be good for applications where their ultrath
 in nature gives them distinct advantages\, such as flexible electronics [1
 ] or light-weight solar cells [2]. They may not be good where conventional
  materials work sufficiently well\, like transistors thicker than a few na
 nometers. I will focus on 2D materials for 3D heterogeneous integration of
  electronics\, which presents major advantages for energy-efficient comput
 ing [3]. Here\, 2D materials could be monolayer transistors with ultralow 
 leakage [4] (due to larger band gaps than silicon)\, used to access high-d
 ensity memory [5]. Recent results from our group [6\,7] and others [8] hav
 e shown monolayer transistors with good performance\, which cannot be achi
 eved with sub-nanometer thin conventional semiconductors\, and the 2D perf
 ormance could be further boosted by strain [9]. I will also describe some 
 unconventional applications\, using 2D materials as thermal insulators [10
 ]\, heat spreaders [11]\, and thermal transistors [12]. These could enable
  control of heat in &ldquo\;thermal circuits&rdquo\; analogous with electr
 ical circuits. Combined\, these studies reveal fundamental limits and some
  unusual applications of 2D materials\, which take advantage of their uniq
 ue properties.</p>\n<p>Refs: [1] A. Daus et al.\, Nat. Elec. 4\, 495 (2021
 ). [2] K. Nassiri Nazif\, et al.\, Nat. Comm. 12\, 7034 (2021). [3] M. Aly
  et al.\, Computer 48\, 24 (2015). [4] C. Bailey et al.\, EMC (2019). [5] 
 A. Khan et al. Science 373\, 1243 (2021). [6] C. English et al.\, IEDM\, D
 ec 2016. [7] C. McClellan et al. ACS Nano 15\, 1587 (2021). [8] S. Das et 
 al.\, Nat. Elec. 4\, 786 (2021). [9] I. Datye et al.\, Nano Lett. 22\, 805
 2 (2022). [10] S. Vaziri et al.\, Science Adv. 5\, eaax1325 (2019). [11] C
 . Koroglu &amp\; E. Pop\, IEEE Elec. Dev. Lett. 44\, 496 (2023). [12] M. C
 hen et al.\, 2D Mater. 8\, 035055 (2021).</p>\n<p>.</p>\n<h3>Speaker Bio:<
 /h3>\n<p>Eric Pop is the Pease-Ye Professor of Electrical Engineering (EE)
  and Materials Science &amp\; Engineering (by courtesy) at Stanford\, wher
 e he leads the SystemX Heterogeneous Integration focus area and the EE Cul
 ture\, Equity\, and Inclusion committee. His research interests include na
 noelectronics\, data storage\, and energy. Before Stanford\, he spent seve
 ral years on the faculty of UIUC\, and in industry at Intel and IBM. He re
 ceived his PhD in EE from Stanford (2005) and three degrees from MIT in EE
  and Physics. His awards include the PECASE from the White House\, and You
 ng Investigator Awards from the Navy\, Air Force\, NSF CAREER\, and DARPA.
  He is an APS and IEEE Fellow\, an Editor of <em>2D Materials</em>\, and a
  Clarivate Highly Cited Researcher. In his spare time he enjoys snowboardi
 ng and tennis\, and in a past life he was a college radio DJ at KZSU 90.1.
  More information about the Pop Lab is available at <a href="http://poplab
 .stanford.edu">http://poplab.stanford.edu</a> and on Twitter <a href="http
 s://twitter.com/profericpop">@profericpop</a>..</p>\n</div>
END:VEVENT
END:VCALENDAR