International Electron Devices Meeting: Difference between revisions

Edit links
From Wikipedia, the free encyclopedia
Browse history interactively
← Previous editNext edit →
Content deleted Content added
VisualWikitext
GaryDag (talk | contribs)
29 edits
m better description and minor update
Rescuing 1 sources and tagging 0 as dead. #IABot (v1.6.1)
Line 3: Line 3:
The IEDM is where "Moore’s Law" got its name -- Gordon Moore first published his predictions in an article in Electronics magazine in 1965. Ten years later he refined them in a talk at the IEDM, and from that point on people began referring to them as Moore's Law. Moore’s Law states that the complexity of integrated circuits would double approximately every two years.<ref>{{cite web|url=http://www.computerhistory.org/semiconductor/timeline/1965-Moore.html |title=1965: "Moore's Law" Predicts the Future of Integrated Circuits &#124; The Silicon Engine &#124; Computer History Museum |publisher=Computerhistory.org |date= |accessdate=2017-03-11}}</ref><ref>{{cite web|url=http://www.newelectronics.co.uk/electronics-technology/the-economics-of-chip-manufacture-on-advanced-technologies/35562/ |title=The economics of chip manufacture on advanced technologies |publisher=Newelectronics.co.uk |date=2011-07-26 |accessdate=2017-03-11}}</ref>
The IEDM is where "Moore’s Law" got its name -- Gordon Moore first published his predictions in an article in Electronics magazine in 1965. Ten years later he refined them in a talk at the IEDM, and from that point on people began referring to them as Moore's Law. Moore’s Law states that the complexity of integrated circuits would double approximately every two years.<ref>{{cite web|url=http://www.computerhistory.org/semiconductor/timeline/1965-Moore.html |title=1965: "Moore's Law" Predicts the Future of Integrated Circuits &#124; The Silicon Engine &#124; Computer History Museum |publisher=Computerhistory.org |date= |accessdate=2017-03-11}}</ref><ref>{{cite web|url=http://www.newelectronics.co.uk/electronics-technology/the-economics-of-chip-manufacture-on-advanced-technologies/35562/ |title=The economics of chip manufacture on advanced technologies |publisher=Newelectronics.co.uk |date=2011-07-26 |accessdate=2017-03-11}}</ref>


'''IEDM''' brings together managers, engineers, and scientists from industry, academia, and government around the world to discuss nanometer-scale [[CMOS]] transistor technology, advanced memory, displays, sensors, [[Microelectromechanical systems|MEMS devices]], novel quantum and [[nanoscale]] devices using emerging phenomena, [[optoelectronics]], power, [[energy harvesting]], and ultra-high-speed devices, as well as process technology and device modeling and simulation. The conference also encompasses discussions and presentations on devices in [[silicon]], [[Compound semiconductor|compound]] and [[Organic semiconductor|organic]] semiconductors, and emerging material systems.<ref>{{cite news | first = Gail | last = Purvis | title = IEDM, where the device is king | date = 15 Nov 2012 | url = http://www.powersystemsdesign.com/iedm-where-the-device-is-king?a=1&c=1151 | work = Power Systems Design | accessdate = 2013-04-25}}</ref> In addition to technical paper presentations, IEDM includes multiple plenary presentations, panel sessions, tutorials, short courses, and invited talks and an entrepreneurship panel session conducted by experts in the field from around the globe.
'''IEDM''' brings together managers, engineers, and scientists from industry, academia, and government around the world to discuss nanometer-scale [[CMOS]] transistor technology, advanced memory, displays, sensors, [[Microelectromechanical systems|MEMS devices]], novel quantum and [[nanoscale]] devices using emerging phenomena, [[optoelectronics]], power, [[energy harvesting]], and ultra-high-speed devices, as well as process technology and device modeling and simulation. The conference also encompasses discussions and presentations on devices in [[silicon]], [[Compound semiconductor|compound]] and [[Organic semiconductor|organic]] semiconductors, and emerging material systems.<ref>{{cite news | first = Gail | last = Purvis | title = IEDM, where the device is king | date = 15 Nov 2012 | url = http://www.powersystemsdesign.com/iedm-where-the-device-is-king?a=1&c=1151 | work = Power Systems Design | accessdate = 2013-04-25 | deadurl = yes | archiveurl = https://web.archive.org/web/20130606220511/http://www.powersystemsdesign.com/iedm-where-the-device-is-king?a=1&c=1151 | archivedate = 2013-06-06 | df = }}</ref> In addition to technical paper presentations, IEDM includes multiple plenary presentations, panel sessions, tutorials, short courses, and invited talks and an entrepreneurship panel session conducted by experts in the field from around the globe.


The 63rd annual IEDM will be held at the Hilton San Francisco Union Square hotel December 2–6, 2017. This year Nobel Prize winner Hiroshi Amano will speak on ‘Transformative Electronics’; AMD President & CEO Lisa Su will speak on multi-chip technologies for high-performance computing; Intel and Globalfoundries will detail their competing new FinFET technology platforms; and IBM’s Dan Edelstein will give a retrospective on copper interconnect. Copper interconnect (i.e., the wiring on computer chips) revolutionized the industry 20 years ago.<ref>http://www-03.ibm.com/ibm/history/ibm100/us/en/icons/copperchip/</ref>
The 63rd annual IEDM will be held at the Hilton San Francisco Union Square hotel December 2–6, 2017. This year Nobel Prize winner Hiroshi Amano will speak on ‘Transformative Electronics’; AMD President & CEO Lisa Su will speak on multi-chip technologies for high-performance computing; Intel and Globalfoundries will detail their competing new FinFET technology platforms; and IBM’s Dan Edelstein will give a retrospective on copper interconnect. Copper interconnect (i.e., the wiring on computer chips) revolutionized the industry 20 years ago.<ref>http://www-03.ibm.com/ibm/history/ibm100/us/en/icons/copperchip/</ref>

Revision as of 01:31, 15 November 2017

The IEEE International Electron Devices Meeting (IEDM) is an annual micro- and nanoelectronics conference held each December that serves as a forum for reporting technological breakthroughs in the areas of semiconductor and related device technologies, design, manufacturing, physics, modeling and circuit-device interaction.[1]

The IEDM is where "Moore’s Law" got its name -- Gordon Moore first published his predictions in an article in Electronics magazine in 1965. Ten years later he refined them in a talk at the IEDM, and from that point on people began referring to them as Moore's Law. Moore’s Law states that the complexity of integrated circuits would double approximately every two years.[2][3]

IEDM brings together managers, engineers, and scientists from industry, academia, and government around the world to discuss nanometer-scale CMOS transistor technology, advanced memory, displays, sensors, MEMS devices, novel quantum and nanoscale devices using emerging phenomena, optoelectronics, power, energy harvesting, and ultra-high-speed devices, as well as process technology and device modeling and simulation. The conference also encompasses discussions and presentations on devices in silicon, compound and organic semiconductors, and emerging material systems.[4] In addition to technical paper presentations, IEDM includes multiple plenary presentations, panel sessions, tutorials, short courses, and invited talks and an entrepreneurship panel session conducted by experts in the field from around the globe.

The 63rd annual IEDM will be held at the Hilton San Francisco Union Square hotel December 2–6, 2017. This year Nobel Prize winner Hiroshi Amano will speak on ‘Transformative Electronics’; AMD President & CEO Lisa Su will speak on multi-chip technologies for high-performance computing; Intel and Globalfoundries will detail their competing new FinFET technology platforms; and IBM’s Dan Edelstein will give a retrospective on copper interconnect. Copper interconnect (i.e., the wiring on computer chips) revolutionized the industry 20 years ago.[5]

The International Electron Devices Meeting is sponsored by the Electron Devices Society of the Institute of Electrical and Electronics Engineers (IEEE).

History

The First Annual Technical Meeting on Electron Devices (renamed the International Electron Devices Meeting in the mid-1960s) took place on October 24–25, 1955 at the Shoreham Hotel in Washington D.C. with approximately 700 scientists and engineers in attendance. At that time, the seven-year-old transistor and the electron tube reigned as the predominant electron-device technology. Fifty-four papers were presented on the then state-of-the-art in electron device technology, the majority of them from four U.S. companies -- Bell Telephone Laboratories, RCA Corporation, Hughes Aircraft Co. and Sylvania Electric Products. The need for an electron devices meeting was driven by two factors: commercial opportunities in the fast-growing new "solid-state" branch of electronics, and the U.S. government's desire for solid-state components and better microwave tubes for aerospace and defense.[6]

IEDM 2016

The 2016 IEEE International Devices Meeting took place at the Hilton San Francisco Union Square from December 3–7, 2016. The 2016 edition of the IEDM emphasized[7]

  • advanced transistors[8]
  • new memory technologies[9]
  • brain-inspired computing[10]
  • bioelectronics[11]
  • power electronics[12]

IEDM 2015

The 2015 International Electron Devices Meeting took place at the Washington Hilton Hotel from December 5–9, 2015. The major topics [13][14] included:

  • ultra-small transistors [15]
  • advanced memories [16]
  • low-power devices for mobile & Internet of Things (IoT) applications [17]
  • alternatives to silicon transistors [18]
  • 3D integrated circuit (IC) technology [19]
  • a broad range of papers addressing some of the fastest-growing specialized areas in micro/nanoelectronics, including silicon photonics,[20] physically flexible circuits [21] and brain-inspired computing [22]

IEDM 2014

The 2014 International Electron Devices Meeting took place at the Hilton San Francisco Union Square from December 15–17, 2014. The 2014 edition of the IEDM emphasized:

  • 14 nm FinFET transistor processes [23]
  • power electronics [24]
  • bio-sensors and MEMS/NEMS technologies for medical applications [25]
  • new memory devices [26]
  • display and sensor technologies [27]
  • 3D device architectures [28]

References

  1. ^ Mokhoff, Nicolas (18 Dec 2006). "Start of a beautiful friendship". EE Times. UBM Tech. Retrieved 2013-04-25.
  2. ^ "1965: "Moore's Law" Predicts the Future of Integrated Circuits | The Silicon Engine | Computer History Museum". Computerhistory.org. Retrieved 2017-03-11.
  3. ^ "The economics of chip manufacture on advanced technologies". Newelectronics.co.uk. 2011-07-26. Retrieved 2017-03-11.
  4. ^ Purvis, Gail (15 Nov 2012). "IEDM, where the device is king". Power Systems Design. Archived from the original on 2013-06-06. Retrieved 2013-04-25. {{cite news}}: Unknown parameter |deadurl= ignored (|url-status= suggested) (help)
  5. ^ http://www-03.ibm.com/ibm/history/ibm100/us/en/icons/copperchip/
  6. ^ McEwan, A.W. (April 1956). "A production model K-band backward wave oscillator". IRE Transactions on Electron Devices. 3 (2): 108. doi:10.1109/T-ED.1956.14115. Retrieved 2013-04-25.
  7. ^ http://semiengineering.com/5-takeaways-from-iedm/
  8. ^ https://www.semiwiki.com/forum/content/6477-iedm-2016-7nm-shootout.html
  9. ^ http://www.eejournal.com/article/20160201-micron/
  10. ^ https://www.eetimes.com/author.asp?section_id=36&doc_id=1331105&page_number=1
  11. ^ https://spectrum.ieee.org/nanoclast/semiconductors/nanotechnology/graphene-temporary-tattoo
  12. ^ http://powerpulse.net/system-level-impact-of-wbg-power-devices-at-2016-iedm-2/
  13. ^ Paul McLellan (2015-12-11). "IEDM: the International Electron Devices Meeting - Breakfast Bytes - Cadence Blogs - Cadence Community". Community.cadence.com. Retrieved 2017-03-11.
  14. ^ by sdavis (2015-12-02). "A Look Ahead at IEDM 2015 | Siliconica". Electroiq.com. Retrieved 2017-03-11.
  15. ^ Stevenson, Richard (2016-01-26). "Nanowire Transistors Could Let You Talk, Text, and Tweet Longer - IEEE Spectrum". Spectrum.ieee.org. Retrieved 2017-03-11.
  16. ^ Tetsuo Nozawa (2015-12-24). "Samsung: DRAM Can Be Scaled Down to 10nm - Nikkei Technology Online". Techon.nikkeibp.co.jp. Retrieved 2017-03-11.
  17. ^ 02:55 PM. "IEDM Blogs – Part 3 – Global Foundries 22FDX Briefing". SemiWiki.com. Retrieved 2017-03-11.{{cite web}}: CS1 maint: numeric names: authors list (link)
  18. ^ Ashok Bindra. "IEDM Divulges Advances in Wide Bandgap Devices | Electronics360". Electronics360.globalspec.com. Retrieved 2017-03-11.
  19. ^ Turley, Jim (2016-02-01). "How It's Built: Micron/Intel 3D NAND". Eejournal.com. Retrieved 2017-03-11.
  20. ^ "Germanium-tin laser for silicon photonics is CMOS compatible". laserfocusworld.com. Retrieved 11 March 2017.
  21. ^ "2015 IEDM Slide 11: RF CMOS Circuits on Flexible, Application-Specific Substrates | Chip Design". Eecatalog.com. 2016-02-09. Retrieved 2017-03-11.
  22. ^ "IEDM 2015 NV Memory and Brain Functions". EE Times. Retrieved 2017-03-11.
  23. ^ "Solid Doping for Bulk FinFETs | Semiconductor Manufacturing & Design Community". Semimd.com. 2015-01-05. Retrieved 2017-03-11.
  24. ^ "Safe and High-Quality Electronic Products -- Smart Grid Electronics". smartgridelectronics.net. Retrieved 11 March 2017.
  25. ^ "Innovative Technologies for DNA Diagnostics and Health Monitoring". Mdtmag.com. Retrieved 2017-03-11.
  26. ^ Morris, Kevin (2015-02-11). "TRAM and PCM at IEDM". EE Journal. Retrieved 2017-03-11.
  27. ^ "CMOS processing advances imaging : Media & Entertainment Technology". Mandetech.com. 2015-01-19. Retrieved 2017-03-11.
  28. ^ "IEDM 2014 3D Shortcourse highlights Importance of 3D Memory Cubes". 3D InCites. 2015-01-05. Retrieved 2017-03-11.

Additional Information

Related Conferences

Retrieved from "https://en.wikipedia.org/w/index.php?title=International_Electron_Devices_Meeting&oldid=810404979"