Thermal Management of Electronics

By Justin Weibel

Mechanical Engineering, Purdue University, West Lafayette, IN

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Bio

image Justin Weibel received his Ph.D. in mechanical engineering from Purdue in 2012 and is a research assistant professor of Mechanical Engineering at Purdue University His research focuses on two-phase electronics cooling and packaging solutions; heat pipe testing, modeling, and design; and thermal system analysis for energy efficiency.

He recently received the 2011 ASME Electronic & Photonic Packaging Division Student Member of the Year Award in recognition of a student who has excelled in research and shown promise to be a strong contributor in the field of electronic and photonic packaging.

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Researchers should cite this work as follows:

  • Justin Weibel (2017), "Thermal Management of Electronics," https://nanohub.org/resources/27676.

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B10, MSEE, Purdue University, West Lafayette, IN

Tags

  1. NCN Group - Thermal Properties
Thermal Management of Electronics
  • Thermal Management of Electronics 1. Thermal Management of Electron… 0
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  • Lecture Topics 2. Lecture Topics 36.770103436770107
    00:00/00:00
  • Further Textbook Reading 3. Further Textbook Reading 115.38204871538206
    00:00/00:00
  • Thermal Management Landscape 4. Thermal Management Landscape 186.18618618618621
    00:00/00:00
  • Computing Trends 5. Computing Trends 364.93159826493161
    00:00/00:00
  • Heat Flux Challenge 6. Heat Flux Challenge 428.36169502836174
    00:00/00:00
  • Other Challenges 7. Other Challenges 557.92459125792459
    00:00/00:00
  • Challenge of Multiple Scales 8. Challenge of Multiple Scales 705.37203870537212
    00:00/00:00
  • Data Center Efficiency 9. Data Center Efficiency 836.77010343677011
    00:00/00:00
  • Waterlogged 10. Waterlogged 925.291958625292
    00:00/00:00
  • IBM Z13 Server 11. IBM Z13 Server 1163.3299966633301
    00:00/00:00
  • Thermal Management Architectures 12. Thermal Management Architectur… 1436.202869536203
    00:00/00:00
  • Simple Resistance Model 13. Simple Resistance Model 1650.6506506506507
    00:00/00:00
  • Interfacial Resistances 14. Interfacial Resistances 1734.8682015348684
    00:00/00:00
  • Thermal Interface Materials (TIM) 15. Thermal Interface Materials (T… 1813.5802469135804
    00:00/00:00
  • Thermal Interface Materials (TIM) 16. Thermal Interface Materials (T… 1890.8241574908243
    00:00/00:00
  • Principles of Conduction 17. Principles of Conduction 1985.4521187854523
    00:00/00:00
  • Integrated Heat Spreader Resistance 18. Integrated Heat Spreader Resis… 2139.6062729396062
    00:00/00:00
  • Principles of Convection 19. Principles of Convection 2260.4938271604938
    00:00/00:00
  • Principles of Convection 20. Principles of Convection 2399.8665331998668
    00:00/00:00
  • Fin Heat Sink Resistance 21. Fin Heat Sink Resistance 2437.7711044377711
    00:00/00:00
  • Fin Heat Sink Resistance 22. Fin Heat Sink Resistance 2492.8595261928594
    00:00/00:00
  • Fin Heat Sink Resistance 23. Fin Heat Sink Resistance 2499.2325658992327
    00:00/00:00
  • Simple Resistance Model 24. Simple Resistance Model 2658.6586586586586
    00:00/00:00
  • Advanced Thermal Management Strategies 25. Advanced Thermal Management St… 2710.3770437103772
    00:00/00:00
  • Next-Gen Thermal Management 26. Next-Gen Thermal Management 2729.72972972973
    00:00/00:00
  • Vapor Chamber and Heat Pipe Spreaders 27. Vapor Chamber and Heat Pipe Sp… 2867.967967967968
    00:00/00:00
  • Principles of Heat Pipe Operation 28. Principles of Heat Pipe Operat… 2875.0083416750085
    00:00/00:00
  • Heat Transfer Performance 29. Heat Transfer Performance 3148.5485485485488
    00:00/00:00
  • Heat Pipe Transport Limits 30. Heat Pipe Transport Limits 3311.2445779112445
    00:00/00:00
  • Heat Pipe Transport Limits 31. Heat Pipe Transport Limits 3381.9486152819486
    00:00/00:00
  • Capillary Limit 32. Capillary Limit 3384.7180513847184
    00:00/00:00
  • Fluid Figures of Merit 33. Fluid Figures of Merit 3466.866866866867
    00:00/00:00
  • Microchannel Heat Sinks 34. Microchannel Heat Sinks 3597.7310643977312
    00:00/00:00
  • Why Microchannels? 35. Why Microchannels? 3610.744077410744
    00:00/00:00
  • A Simple Calculation 36. A Simple Calculation 3656.5565565565566
    00:00/00:00
  • Single-Phase Heat Transfer 37. Single-Phase Heat Transfer 3657.4908241574908
    00:00/00:00
  • Single-Phase Conclusions 38. Single-Phase Conclusions 3658.4918251584918
    00:00/00:00
  • Two Phase Flow in Microchannels 39. Two Phase Flow in Microchannel… 3659.4594594594596
    00:00/00:00
  • Two Phase Flow in Microchannels 40. Two Phase Flow in Microchannel… 3660.3603603603606
    00:00/00:00
  • Flow Regime Prediction and Models 41. Flow Regime Prediction and Mod… 3702.3023023023025
    00:00/00:00
  • Current Challenges/Needs 42. Current Challenges/Needs 3704.4711378044713
    00:00/00:00
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