Illinois ECE 598EP Lecture 1 - Hot Chips: Atoms to Heat Sinks

View Presentation (SWF)

Licensed according to this deed.

Published on

Abstract

Introduction

Content:

  • The Big Picture
  • Another CPU without a Heat Sink
  • Thermal Management Methods
  • Impact on People and Environment
  • Packaging cost
  • IBM S/390 refrigeration and processor packaging
  • Intel Itanium and Pentium 4packaging
  • Graphics Cards
  • Under/Overclocking
  • Environment
  • A More Detailed Look
  • Thermal Management Methods
  • Where Does the Heat Come From?
  • More on Chip-Level Complexity
  • Temporal, Spatial Variations
  • Variations Depending on Application
  • Temperature Affects
  • Thermal Interconnect Failure
  • Chip-Level Thermal Challenges
  • Why (down)Scaling?
  • CMOS Power Issue: Active vs. Passive
  • Power and Heat Limit Frequency Scaling
  • Has This Ever Happened Before?
  • Implications for Nanoscale Circuits
  • Transistor-Level Thermal Challenges
  • The Tiny Picture
  • K of Nano, RB of Interfaces
  • Thermal Resistance at Device Level
  • Thermal Resistance, Electrical Resistance
  • This Heating Business is Not All Bad…
  • Nanotubes in the Carbon World
  • Why Carbon Nanotubes and Graphene?
  • Light Emission from Metallic SWNTs
  • Extracting SWNT Thermal Conductivity
  • What Is Phase-Change Memory?
  • How Phase-Change Materials Works
  • Samsung 512 Mb PCM Prototype
  • Intel/ST Phase-Change Memory Wafer

Credits

Breezed and uploaded by Omar Sobh

Sponsored by

NCN@Illinois

Cite this work

Researchers should cite this work as follows:

  • Eric Pop (2009), "Illinois ECE 598EP Lecture 1 - Hot Chips: Atoms to Heat Sinks," http://nanohub.org/resources/6184.

    BibTex | EndNote

Tags

  1. Illinois
  2. course lecture
  3. material properties
  4. materials science
  5. materials
  6. nanoelectronics
  7. thermal effect
  8. thermal energy
  9. thermal transport
  10. course lecture
  11. Illinois
  12. material properties
  13. materials science
  14. materials
  15. nanoelectronics
  16. thermal effect
  17. thermal energy
  18. thermal transport