Semiconductors and Sustainability

By John Howater

Materials Engineering, Purdue University, West Lafayette, IN

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Bio

John Howarter John Howarter is an Associate Professor of Materials Engineering and Environmental and Ecological Engineering at Purdue University. He earned his PhD in Materials Engineering from Purdue in 2008. Prior to joining the faculty at Purdue he held a NRC Postdoctoral Fellowship in the Polymers Division at the National Institute of Standards and Technology (NIST). His research interests are centered around reducing the operational energy footprint of polymer membranes through material design. This includes a focus on material improvements of polyamide membranes used in desalination and functional composite membranes for targeted separation of industrial wastewater.

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Researchers should cite this work as follows:

  • John Howater (2024), "Semiconductors and Sustainability," https://nanohub.org/resources/38306.

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  1. chips
  2. Educators
  3. K-12
  4. manufacturing
  5. SCALE K-12
  6. SCALE@Purdue
  7. SCALE (Scalable Asymmetric Lifecycle Engagement)
  8. semiconductors
  9. sustainability
Semiconductors and Sustainability
  • Semiconductors and Sustainability 1. Semiconductors and Sustainabil… 0
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  • John Howarter – Sustainable Materials and Manufacturing 2. John Howarter – Sustainable … 37.837837837837839
    00:00/00:00
  • Research Needs: Sustainability Engineering 3. Research Needs: Sustainability… 359.12579245912582
    00:00/00:00
  • Interventions and other mechanisms that influence the flows in the material life cycle 4. Interventions and other mechan… 458.12479145812483
    00:00/00:00
  • Sankey diagram for the flow of aluminum through the economy 5. Sankey diagram for the flow of… 694.66132799466141
    00:00/00:00
  • Stages of Technology 6. Stages of Technology 845.34534534534532
    00:00/00:00
  • Abundance of elements in earth's crust 7. Abundance of elements in earth… 964.63129796463136
    00:00/00:00
  • Sustainability in Complex Products 8. Sustainability in Complex Prod… 1010.7440774107441
    00:00/00:00
  • Measures contributing to material efficiency. 9. Measures contributing to mater… 1193.6603269936604
    00:00/00:00
  • The 1.7 kilogram microchip 10. The 1.7 kilogram microchip 1316.9502836169504
    00:00/00:00
  • Circularity measurement methodology 11. Circularity measurement method… 1488.4884884884887
    00:00/00:00
  • Manufacturing Example for Circularity 12. Manufacturing Example for Circ… 1609.5762429095762
    00:00/00:00
  • Silicon Crystal Growth 13. Silicon Crystal Growth 1701.1678345011678
    00:00/00:00
  • Wafer production 14. Wafer production 1789.3226559893228
    00:00/00:00
  • Stacked Chips 15. Stacked Chips 1837.2706039372706
    00:00/00:00
  • Die Stacking Technology 16. Die Stacking Technology 1902.9696363029698
    00:00/00:00
  • NAND gate (negative-AND) 17. NAND gate (negative-AND) 1971.0710710710712
    00:00/00:00
  • Characterization of Lead-Free Solders 18. Characterization of Lead-Free … 1994.2275608942277
    00:00/00:00
  • Composition of E-waste 19. Composition of E-waste 2062.6292959626294
    00:00/00:00
  • Urban mining 20. Urban mining "deposits" 2171.6716716716719
    00:00/00:00
  • Environmental Science and Technology, 2013 21. Environmental Science and Tech… 2239.2058725392058
    00:00/00:00
  • Currently ID'd Research Areas 22. Currently ID'd Research Areas 2365.765765765766
    00:00/00:00
  • Core Questions for Big Sustainability Challenges 23. Core Questions for Big Sustain… 2515.2819486152821
    00:00/00:00
  • Research Needs: Sustainability Engineering 24. Research Needs: Sustainability… 2540.6406406406409
    00:00/00:00
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