Book - Fab 101: Difference between revisions
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*Trace size limits and lithography | *Trace size limits and lithography | ||
*Future directions - optical for speed (100x faster than electrons [https://www.google.com/search?q=how+fast+do+electrons+move+compared+to+the+speed+of+light&oq=how+fast+do+electrons+move+compared+to+the+speed+of+light&aqs=chrome..69i57l2j69i60l4.8749j0j7&client=ubuntu&sourceid=chrome&ie=UTF-8]), genetic for memory | *Future directions - optical for speed (100x faster than electrons [https://www.google.com/search?q=how+fast+do+electrons+move+compared+to+the+speed+of+light&oq=how+fast+do+electrons+move+compared+to+the+speed+of+light&aqs=chrome..69i57l2j69i60l4.8749j0j7&client=ubuntu&sourceid=chrome&ie=UTF-8]), genetic for memory | ||
*Size of facility and equipment needed | |||
Revision as of 17:26, 19 January 2019
Discussion of what is required for the most advanced technology on Earth - Very Large Scale Integrated circuits - aka microchips.
- Air bearings. The ball bearing created the industrial age. The air bearing created the digital age
- Vessels - vacuum chambers pumped by air bearing-containing turbo pumps
- Sand and trace chemicals
- First integrated circuit in the 50s
- Technology requires in the 80s - Large Scale Integration
- Trace size limits and lithography
- Future directions - optical for speed (100x faster than electrons [1]), genetic for memory
- Size of facility and equipment needed