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DTSTAMP:20251022T045536Z
UID:11D8B414-5C14-4B85-A003-4520D320F795
DTSTART;TZID=America/Los_Angeles:20251020T160000
DTEND;TZID=America/Los_Angeles:20251020T173000
DESCRIPTION:Ultrasound is utilized in diverse industries such as MedTech (e
 .g. for imaging\, therapy\, photoacoustic) or measurement and analysis (e.
 g. flow flow rate measurement\, material characterization\, non-destructiv
 e testing). Conventional piezoelectric transducers have been by far primar
 y technologies in ubiquitous applications of ultrasound. Capacitive microm
 achined ultrasound transducer (CMUT) is an all-silicon ultrasound technolo
 gy that emerges as an attractive alternative\, and furthermore drives towa
 rd new applications. These silicon-based transducers offer not only limitl
 ess miniaturization of transducers or their batch production\, but also un
 ique advantages such as wide bandwidth (&gt; 100 %)\, better impedance matchi
 ng\, high temperature tolerance (&gt;200 °C)\, and no self-heating. This tal
 k aims to provide an overview of the technology\, from design to manufactu
 ring\, as well as a few demonstrated applications.\n\nSpeaker(s): Nooshin\
 , Nooshin\n\nAgenda: \nUltrasound is utilized in diverse industries such a
 s MedTech (e.g. for imaging\, therapy\, photoacoustic) or measurement and 
 analysis (e.g. flow flow rate measurement\, material characterization\, no
 n-destructive testing). Conventional piezoelectric transducers have been b
 y far primary technologies in ubiquitous applications of ultrasound. Capac
 itive micromachined ultrasound transducer (CMUT) is an all-silicon ultraso
 und technology that emerges as an attractive alternative\, and furthermore
  drives toward new applications. These silicon-based transducers offer not
  only limitless miniaturization of transducers or their batch production\,
  but also unique advantages such as wide bandwidth (&gt; 100 %)\, better impe
 dance matching\, high temperature tolerance (&gt;200 °C)\, and no self-heati
 ng. This talk aims to provide an overview of the technology\, from design 
 to manufacturing\, as well as a few demonstrated applications.\n\nRoom: AS
 B 10704\, Bldg: Applied Sciences Building\, Simon Fraser University\, 8888
  Univeristy Drive\, Burnaby\, British Columbia\, Canada\, V5A 1S6\, Virtua
 l: https://events.vtools.ieee.org/m/507459
LOCATION:Room: ASB 10704\, Bldg: Applied Sciences Building\, Simon Fraser U
 niversity\, 8888 Univeristy Drive\, Burnaby\, British Columbia\, Canada\, 
 V5A 1S6\, Virtual: https://events.vtools.ieee.org/m/507459
ORGANIZER:ljilja@cs.sfu.ca
SEQUENCE:40
SUMMARY:Silicon MEMS Ultrasound: Technology and Applications
URL;VALUE=URI:https://events.vtools.ieee.org/m/507459
X-ALT-DESC:Description: &lt;br /&gt;&lt;p class=&quot;MsoNormal&quot;&gt;&lt;span style=&quot;font-family
 : &#39;Arial&#39;\,sans-serif\; mso-fareast-font-family: &#39;Times New Roman&#39;\; mso-a
 nsi-language: EN-CA\;&quot;&gt;Ultrasound is utilized in diverse industries such a
 s MedTech (e.g.&amp;nbsp\; for imaging\, therapy\, photoacoustic) or measureme
 nt and analysis (e.g.&amp;nbsp\; flow flow rate measurement\, material charact
 erization\, non-destructive testing). Conventional piezoelectric transduce
 rs have been by far primary technologies in ubiquitous applications of ult
 rasound. Capacitive micromachined ultrasound transducer (CMUT) is an all-s
 ilicon ultrasound technology that emerges as an attractive alternative\, a
 nd furthermore drives toward new applications.&amp;nbsp\; These silicon-based 
 transducers offer not only limitless miniaturization of transducers or the
 ir batch production\, but also unique advantages such as wide bandwidth (&amp;
 gt\; 100 %)\, better impedance matching\, high temperature tolerance (&amp;gt\
 ;200 &amp;deg\;C)\, and no self-heating. This talk aims to provide an overview
  of the technology\, from design to manufacturing\, as well as a few demon
 strated applications.&lt;/span&gt;&lt;/p&gt;&lt;br /&gt;&lt;br /&gt;Agenda: &lt;br /&gt;&lt;p class=&quot;MsoNor
 mal&quot;&gt;&lt;span style=&quot;font-family: &#39;Arial&#39;\,sans-serif\; mso-fareast-font-fami
 ly: &#39;Times New Roman&#39;\; mso-ansi-language: EN-CA\;&quot;&gt;Ultrasound is utilized
  in diverse industries such as MedTech (e.g.&amp;nbsp\; for imaging\, therapy\
 , photoacoustic) or measurement and analysis (e.g.&amp;nbsp\; flow flow rate m
 easurement\, material characterization\, non-destructive testing). Convent
 ional piezoelectric transducers have been by far primary technologies in u
 biquitous applications of ultrasound. Capacitive micromachined ultrasound 
 transducer (CMUT) is an all-silicon ultrasound technology that emerges as 
 an attractive alternative\, and furthermore drives toward new applications
 .&amp;nbsp\; These silicon-based transducers offer not only limitless miniatur
 ization of transducers or their batch production\, but also unique advanta
 ges such as wide bandwidth (&amp;gt\; 100 %)\, better impedance matching\, hig
 h temperature tolerance (&amp;gt\;200 &amp;deg\;C)\, and no self-heating. This tal
 k aims to provide an overview of the technology\, from design to manufactu
 ring\, as well as a few demonstrated applications.&lt;/span&gt;&lt;/p&gt;
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