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DTSTAMP:20231024T024255Z
UID:6A1110DF-F5BA-489F-A56E-928122BFDB0B
DTSTART;TZID=America/Los_Angeles:20231020T090000
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DESCRIPTION:The Electron Devices Society Santa Clara Valley/San Francisco j
 oint Chapter is hosting Prof. Meenakshi Singh. The title of the lecture is
  ‘Investigating quantum speed limits with superconducting qubits’\n\nW
 hen: Friday\, Oct. 20\, 2023 – 9am to 10am (PDT)\n\nWhere: This is an on
 line event and attendees can participate via Zoom.\n\nRegistration: Send a
 n email to hiuyung.wong at ieee.org to get the zoom link indicating if you
  are IEEE member\, IEEE EDS member\, IEEE Student member\n\nContact: hiuyu
 ng.wong at ieee.org\n\nSpeaker: Prof. Meenakshi Singh\n\nAbstract:\n\nThe 
 speed at which quantum entanglement between qubits with short range intera
 ctions can be generated is limited by the Lieb-Robinson bound. Introducing
  longer range interactions relaxes this bound and entanglement can be gene
 rated at a faster rate. The speed limit for this has been analytically fou
 nd only for a two-qubit system under the assumption of negligible single q
 ubit gate time. We seek to demonstrate this speed limit experimentally usi
 ng two superconducting transmon qubits. Moreover\, we aim to measure the i
 ncrease in this speed limit induced by introducing additional qubits (coup
 led with the first two). Since the speed up grows with additional entangle
 d qubits\, it is expected to increase as the system size increases. This h
 as important implications for large-scale quantum computing.\n\nSpeaker Bi
 o:\n\nDr. Singh is an experimental physicist with research focused on quan
 tum thermal effects and quantum computing. She graduated from the Indian I
 nstitute of Technology with an M. S. in Physics in 2006 and received a Ph.
  D. in Physics from the Pennsylvania State University in 2012. Her Ph. D. 
 thesis was focused on quantum transport in nanowires. She went on to work 
 at Sandia National Laboratories on Quantum Computing as a post-doctoral sc
 holar. She is currently an Associate Professor in the Department of Physic
 s at the Colorado School of Mines. At Mines\, her research projects includ
 e measurements of spin-orbit coupling in novel materials and thermal effec
 ts in superconducting hybrids. She recently received the NSF CAREER award 
 to pursue research in phonon interactions with spin qubits in silicon quan
 tum dots.\n\nSpeaker(s): Prof. Meenakshi Singh\n\nAgenda: \nThe Electron D
 evices Society Santa Clara Valley/San Francisco joint Chapter is hosting P
 rof. Meenakshi Singh. The title of the lecture is ‘Investigating quantum
  speed limits with superconducting qubits’\n\nWhen: Friday\, Oct. 20\, 2
 023 – 9am to 10am (PDT)\n\nWhere: This is an online event and attendees 
 can participate via Zoom.\n\nRegistration: Send an email to hiuyung.wong a
 t ieee.org to get the zoom link indicating if you are IEEE member\, IEEE E
 DS member\, IEEE Student member\n\nContact: hiuyung.wong at ieee.org\n\nSp
 eaker: Prof. Meenakshi Singh\n\nAbstract:\n\nThe speed at which quantum en
 tanglement between qubits with short range interactions can be generated i
 s limited by the Lieb-Robinson bound. Introducing longer range interaction
 s relaxes this bound and entanglement can be generated at a faster rate. T
 he speed limit for this has been analytically found only for a two-qubit s
 ystem under the assumption of negligible single qubit gate time. We seek t
 o demonstrate this speed limit experimentally using two superconducting tr
 ansmon qubits. Moreover\, we aim to measure the increase in this speed lim
 it induced by introducing additional qubits (coupled with the first two). 
 Since the speed up grows with additional entangled qubits\, it is expected
  to increase as the system size increases. This has important implications
  for large-scale quantum computing.\n\nSpeaker Bio:\n\nDr. Singh is an exp
 erimental physicist with research focused on quantum thermal effects and q
 uantum computing. She graduated from the Indian Institute of Technology wi
 th an M. S. in Physics in 2006 and received a Ph. D. in Physics from the P
 ennsylvania State University in 2012. Her Ph. D. thesis was focused on qua
 ntum transport in nanowires. She went on to work at Sandia National Labora
 tories on Quantum Computing as a post-doctoral scholar. She is currently a
 n Associate Professor in the Department of Physics at the Colorado School 
 of Mines. At Mines\, her research projects include measurements of spin-or
 bit coupling in novel materials and thermal effects in superconducting hyb
 rids. She recently received the NSF CAREER award to pursue research in pho
 non interactions with spin qubits in silicon quantum dots.\n\nVirtual: htt
 ps://events.vtools.ieee.org/m/377193
LOCATION:Virtual: https://events.vtools.ieee.org/m/377193
ORGANIZER:hiuyung.wong@ieee.org 
SEQUENCE:16
SUMMARY:EDS Event: Investigating quantum speed limits with superconducting 
 qubits
URL;VALUE=URI:https://events.vtools.ieee.org/m/377193
X-ALT-DESC:Description: <br /><div>\n<p>The Electron Devices Society Santa 
 Clara Valley/San Francisco joint Chapter is hosting Prof. Meenakshi Singh.
  The title of the lecture is &lsquo\;Investigating quantum speed limits wi
 th superconducting qubits&rsquo\;</p>\n<h3>When: Friday\, Oct. 20\, 2023 &
 ndash\; 9am to 10am (PDT)</h3>\n<h3>Where: This is an online event and att
 endees can participate via Zoom.</h3>\n<h3>Registration: Send an email to 
 hiuyung.wong at ieee.org to get the zoom link indicating if you are IEEE m
 ember\, IEEE EDS member\, IEEE Student member</h3>\n<h4>Contact: <span cla
 ss="gI"><span class="qu" role="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. Meenakshi Singh<br /></strong></h2>\n<h3>Abstract:</
 h3>\n<p>The speed at which quantum entanglement between qubits with short 
 range interactions can be generated is limited by the Lieb-Robinson bound.
  Introducing longer range interactions relaxes this bound and entanglement
  can be generated at a faster rate. The speed limit for this has been anal
 ytically found only for a two-qubit system under the assumption of negligi
 ble single qubit gate time. We seek to demonstrate this speed limit experi
 mentally using two superconducting transmon qubits. Moreover\, we aim to m
 easure the increase in this speed limit induced by introducing additional 
 qubits (coupled with the first two). Since the speed up grows with additio
 nal entangled qubits\, it is expected to increase as the system size incre
 ases. This has important implications for large-scale quantum computing.</
 p>\n<h3>Speaker Bio:</h3>\n<p>Dr. Singh is an experimental physicist with 
 research focused on quantum thermal effects and quantum computing. She gra
 duated from the Indian Institute of Technology with an M. S. in Physics in
  2006 and received a Ph. D. in Physics from the Pennsylvania State Univers
 ity in 2012. Her Ph. D. thesis was focused on quantum transport in nanowir
 es. She went on to work at Sandia National Laboratories on Quantum Computi
 ng as a post-doctoral scholar. She is currently an Associate Professor in 
 the Department of Physics at the Colorado School of Mines. At Mines\, her 
 research projects include measurements of spin-orbit coupling in novel mat
 erials and thermal effects in superconducting hybrids. She recently receiv
 ed the NSF CAREER award to pursue research in phonon interactions with spi
 n qubits in silicon quantum dots.</p>\n</div><br /><br />Agenda: <br /><di
 v>\n<p>The Electron Devices Society Santa Clara Valley/San Francisco joint
  Chapter is hosting Prof. Meenakshi Singh. The title of the lecture is &ls
 quo\;Investigating quantum speed limits with superconducting qubits&rsquo\
 ;</p>\n<h3>When: Friday\, Oct. 20\, 2023 &ndash\; 9am to 10am (PDT)</h3>\n
 <h3>Where: This is an online event and attendees can participate via Zoom.
 </h3>\n<h3>Registration: Send an email to hiuyung.wong at ieee.org to get 
 the zoom link indicating if you are IEEE member\, IEEE EDS member\, IEEE S
 tudent member</h3>\n<h4>Contact: <span class="gI"><span class="qu" role="g
 ridcell"><span class="go">hiuyung.wong at ieee.org</span></span></span></h
 4>\n</div>\n<h2>&nbsp\;</h2>\n<div>\n<h2><strong>Speaker: Prof. Meenakshi 
 Singh<br /></strong></h2>\n<h3>Abstract:</h3>\n<p>The speed at which quant
 um entanglement between qubits with short range interactions can be genera
 ted is limited by the Lieb-Robinson bound. Introducing longer range intera
 ctions relaxes this bound and entanglement can be generated at a faster ra
 te. The speed limit for this has been analytically found only for a two-qu
 bit system under the assumption of negligible single qubit gate time. We s
 eek to demonstrate this speed limit experimentally using two superconducti
 ng transmon qubits. Moreover\, we aim to measure the increase in this spee
 d limit induced by introducing additional qubits (coupled with the first t
 wo). Since the speed up grows with additional entangled qubits\, it is exp
 ected to increase as the system size increases. This has important implica
 tions for large-scale quantum computing.</p>\n<h3>Speaker Bio:</h3>\n<p>Dr
 . Singh is an experimental physicist with research focused on quantum ther
 mal effects and quantum computing. She graduated from the Indian Institute
  of Technology with an M. S. in Physics in 2006 and received a Ph. D. in P
 hysics from the Pennsylvania State University in 2012. Her Ph. D. thesis w
 as focused on quantum transport in nanowires. She went on to work at Sandi
 a National Laboratories on Quantum Computing as a post-doctoral scholar. S
 he is currently an Associate Professor in the Department of Physics at the
  Colorado School of Mines. At Mines\, her research projects include measur
 ements of spin-orbit coupling in novel materials and thermal effects in su
 perconducting hybrids. She recently received the NSF CAREER award to pursu
 e research in phonon interactions with spin qubits in silicon quantum dots
 .</p>\n</div>
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