Combat Hybrid Power System Component Technologies: Technical Challenges and Research Priorities (2002)
Chapter: 4 High-temperature, Wideband Gap Materials for High-power Electric Power Conditioning
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Previous Chapter:
3 Battery Technologies for Military Hybrid Vehicle Applications
Next Chapter: 5 High-power Switching Technologies
Suggested Citation:
"4 High-temperature, Wideband Gap Materials for High-power Electric Power Conditioning." National Research Council. 2002. Combat Hybrid Power System Component Technologies: Technical Challenges and Research Priorities. Washington, DC: The National Academies Press.
doi: 10.17226/10595.
Suggested Citation:
"4 High-temperature, Wideband Gap Materials for High-power Electric Power Conditioning." National Research Council. 2002. Combat Hybrid Power System Component Technologies: Technical Challenges and Research Priorities. Washington, DC: The National Academies Press.
doi: 10.17226/10595.
Suggested Citation:
"4 High-temperature, Wideband Gap Materials for High-power Electric Power Conditioning." National Research Council. 2002. Combat Hybrid Power System Component Technologies: Technical Challenges and Research Priorities. Washington, DC: The National Academies Press.
doi: 10.17226/10595.
Suggested Citation:
"4 High-temperature, Wideband Gap Materials for High-power Electric Power Conditioning." National Research Council. 2002. Combat Hybrid Power System Component Technologies: Technical Challenges and Research Priorities. Washington, DC: The National Academies Press.
doi: 10.17226/10595.
Suggested Citation:
"4 High-temperature, Wideband Gap Materials for High-power Electric Power Conditioning." National Research Council. 2002. Combat Hybrid Power System Component Technologies: Technical Challenges and Research Priorities. Washington, DC: The National Academies Press.
doi: 10.17226/10595.
Suggested Citation:
"4 High-temperature, Wideband Gap Materials for High-power Electric Power Conditioning." National Research Council. 2002. Combat Hybrid Power System Component Technologies: Technical Challenges and Research Priorities. Washington, DC: The National Academies Press.
doi: 10.17226/10595.
Suggested Citation:
"4 High-temperature, Wideband Gap Materials for High-power Electric Power Conditioning." National Research Council. 2002. Combat Hybrid Power System Component Technologies: Technical Challenges and Research Priorities. Washington, DC: The National Academies Press.
doi: 10.17226/10595.
Suggested Citation:
"4 High-temperature, Wideband Gap Materials for High-power Electric Power Conditioning." National Research Council. 2002. Combat Hybrid Power System Component Technologies: Technical Challenges and Research Priorities. Washington, DC: The National Academies Press.
doi: 10.17226/10595.
Suggested Citation:
"4 High-temperature, Wideband Gap Materials for High-power Electric Power Conditioning." National Research Council. 2002. Combat Hybrid Power System Component Technologies: Technical Challenges and Research Priorities. Washington, DC: The National Academies Press.
doi: 10.17226/10595.
Suggested Citation:
"4 High-temperature, Wideband Gap Materials for High-power Electric Power Conditioning." National Research Council. 2002. Combat Hybrid Power System Component Technologies: Technical Challenges and Research Priorities. Washington, DC: The National Academies Press.
doi: 10.17226/10595.
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