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DESCRIPTION:Title: Chip-Scale Wave-Matter Interactions at RF-to-Light Frequ
 encies: Circuits\, Systems and Applications\n\nAbstract: Traditional elect
 romagnetic (EM) spectral sensors using integrated circuit technologies (e.
 g. automotive radars\, security imagers\, cameras\, etc.) are normally bas
 ed on wave scattering or absorption by macroscopic objects at remote dista
 nce\; the operations are also not specific in wave frequencies. In the pas
 t couple of years\, a new paradigm of chip-scale EM spectral sensing emerg
 es with features complementary to the above: they utilize various modaliti
 es of interactions between EM waves with highprecision frequency control a
 nd microscopic particles (molecules\, atoms\, etc.) in close proximity to 
 the chip. This progress is enabled by the recent advances of silicon devic
 es and processes\, especially the increase of circuit operation frequencie
 s into the terahertz regime. Chip-scale sensing and metrology systems with
  new capabilities\, higher performance and unprecedented affordability now
  become possible. Examples include THz gas spectroscopy sensors\, on-chip 
 “atomic-clock-grade” frequency references\, room-temperature CMOS-quan
 tum magnetometers\, etc. This talk will present the basic physics of a few
  types of wave-matter interactions\, key enabling technologies\, as well a
 s the designs and prototypes of chip systems. We will also discuss their p
 otential applications in bio-chemical analysis\, wireless networks\, PNT (
 positioning\, navigation & timing)\, security and so on.\n\nBio: Ruonan Ha
 n received the B.Sc. degree in microelectronics from Fudan University\, in
  2007\, the M.Sc. degree in electrical engineering from the University of 
 Florida in 2009\, and the Ph.D. degree in electrical and computer engineer
 ing from Cornell University in 2014. He has been with the Department of El
 ectrical Engineering and Computer Science\, MIT\, since July 2014\, and is
  now an associate professor. His research group at MIT focuses on RF-to-ph
 otonics integrated circuits and systems for spectroscopy\, metrology\, ima
 ging\, quantum sensing/processing\, broadband/secure communication\, etc. 
 He was the\n\nrecipient of the Cornell ECE Directors Ph.D. Thesis Research
  Award\, Cornell ECE Innovation Award\, and two Best Student Paper Awards 
 of the IEEE Radio-Frequency Integrated Circuits Symposium (2012 and 2017).
  He was also the recipient of the IEEE Microwave Theory and Techniques Soc
 iety (MTT-S) Graduate Fellowship Award\, and the IEEE Solid-State Circuits
  Society (SSC-S) Predoctoral Achievement Award. He is an associate editor 
 of IEEE Transactions on Very-Large-Scale Integration System and IEEE Trans
 actions on Quantum Engineering\, a guest associate editor of IEEE Transact
 ions on Microwave Theory and Techniques (2019)\, and also serves on the Te
 chnical Program Committee (TPC) of IEEE RFIC Symposium (2017~present) and 
 the Steering Committee and TPC of 2019 IEEE International Microwave Sympos
 ium. He is the IEEE MTT-S Distinguished Microwave Lecturer (2020-2022). He
  won the Intel Outstanding Researcher Award in 2019 and the National Scien
 ce Foundation (NSF) CAREER Award in 2017.\n\nBuffalo\, New York\, United S
 tates\, Virtual: https://events.vtools.ieee.org/m/271013
LOCATION:Buffalo\, New York\, United States\, Virtual: https://events.vtool
 s.ieee.org/m/271013
ORGANIZER:jmmoskal@ieee.org
SEQUENCE:2
SUMMARY:Chip-Scale Wave-Matter Interactions at RF -to-Light Frequencies: Ci
 rcuits\, Systems\, and Applications
URL;VALUE=URI:https://events.vtools.ieee.org/m/271013
X-ALT-DESC:Description: <br /><p>&nbsp\;</p>\n<p><strong>Title:&nbsp\; </st
 rong>Chip-Scale Wave-Matter Interactions at RF-to-Light Frequencies: Circu
 its\, Systems and Applications</p>\n<p><strong>&nbsp\;</strong></p>\n<p><s
 trong>Abstract:</strong>&nbsp\; Traditional electromagnetic (EM) spectral 
 sensors using integrated circuit technologies (e.g. automotive radars\, se
 curity imagers\, cameras\, etc.) are normally based on wave scattering or 
 absorption by macroscopic objects at remote distance\; the operations are 
 also not specific in wave frequencies. In the past couple of years\, a new
  paradigm of chip-scale EM spectral sensing emerges with features compleme
 ntary to the above: they utilize various modalities of interactions betwee
 n EM waves with highprecision frequency control and microscopic particles 
 (molecules\, atoms\, etc.) in close proximity to the chip. This progress i
 s enabled by the recent advances of silicon devices and processes\, especi
 ally the increase of circuit operation frequencies into the terahertz regi
 me. Chip-scale sensing and metrology systems with new capabilities\, highe
 r performance and unprecedented affordability now become possible. Example
 s include THz gas spectroscopy sensors\, on-chip &ldquo\;atomic-clock-grad
 e&rdquo\; frequency references\, room-temperature CMOS-quantum magnetomete
 rs\, etc. This talk will present the basic physics of a few types of wave-
 matter interactions\, key enabling technologies\, as well as the designs a
 nd prototypes of chip systems. We will also discuss their potential applic
 ations in bio-chemical analysis\, wireless networks\, PNT (positioning\, n
 avigation &amp\; timing)\, security and so on.</p>\n<p><strong>&nbsp\;</st
 rong></p>\n<p><strong>Bio:</strong>&nbsp\; Ruonan Han received the B.Sc. d
 egree in microelectronics from Fudan University\, in 2007\, the M.Sc. degr
 ee in electrical engineering from the University of Florida in 2009\, and 
 the Ph.D. degree in electrical and computer engineering from Cornell Unive
 rsity in 2014. He has been with the Department of Electrical Engineering a
 nd Computer Science\, MIT\, since July 2014\, and is now an associate prof
 essor. His research group at MIT focuses on RF-to-photonics integrated cir
 cuits and systems for spectroscopy\, metrology\, imaging\, quantum sensing
 /processing\, broadband/secure communication\, etc. He was the</p>\n<p>rec
 ipient of the Cornell ECE Directors Ph.D. Thesis Research Award\, Cornell 
 ECE Innovation Award\, and two Best Student Paper Awards of the IEEE Radio
 -Frequency Integrated Circuits Symposium (2012 and 2017). He was also the 
 recipient of the IEEE Microwave Theory and Techniques Society (MTT-S) Grad
 uate Fellowship Award\, and the IEEE Solid-State Circuits Society (SSC-S) 
 Predoctoral Achievement Award. He is an associate editor of IEEE Transacti
 ons on Very-Large-Scale Integration System and IEEE Transactions on Quantu
 m Engineering\, a guest associate editor of IEEE Transactions on Microwave
  Theory and Techniques (2019)\, and also serves on the Technical Program C
 ommittee (TPC) of IEEE RFIC Symposium (2017~present) and the Steering Comm
 ittee and TPC of 2019 IEEE International Microwave Symposium. He is the IE
 EE MTT-S Distinguished Microwave Lecturer (2020-2022). He won the Intel Ou
 tstanding Researcher Award in 2019 and the National Science Foundation (NS
 F) CAREER Award in 2017.</p>
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