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High thermal conductivity in wafer-scale cubic silicon carbide crystals

Author

Listed:
  • Zhe Cheng

    (University of Illinois at Urbana-Champaign)

  • Jianbo Liang

    (Osaka Metropolitan University)

  • Keisuke Kawamura

    (SIC Division, Air Water Inc.)

  • Hao Zhou

    (University of Utah)

  • Hidetoshi Asamura

    (Specialty Materials Dept., Electronics Unit)

  • Hiroki Uratani

    (SIC Division, Air Water Inc.)

  • Janak Tiwari

    (University of Utah)

  • Samuel Graham

    (Georgia Institute of Technology)

  • Yutaka Ohno

    (Tohoku University)

  • Yasuyoshi Nagai

    (Tohoku University)

  • Tianli Feng

    (University of Utah)

  • Naoteru Shigekawa

    (Osaka Metropolitan University)

  • David G. Cahill

    (University of Illinois at Urbana-Champaign)

Abstract

High thermal conductivity electronic materials are critical components for high-performance electronic and photonic devices as both active functional materials and thermal management materials. We report an isotropic high thermal conductivity exceeding 500 W m−1K−1 at room temperature in high-quality wafer-scale cubic silicon carbide (3C-SiC) crystals, which is the second highest among large crystals (only surpassed by diamond). Furthermore, the corresponding 3C-SiC thin films are found to have record-high in-plane and cross-plane thermal conductivity, even higher than diamond thin films with equivalent thicknesses. Our results resolve a long-standing puzzle that the literature values of thermal conductivity for 3C-SiC are lower than the structurally more complex 6H-SiC. We show that the observed high thermal conductivity in this work arises from the high purity and high crystal quality of 3C-SiC crystals which avoids the exceptionally strong defect-phonon scatterings. Moreover, 3C-SiC is a SiC polytype which can be epitaxially grown on Si. We show that the measured 3C-SiC-Si thermal boundary conductance is among the highest for semiconductor interfaces. These findings provide insights for fundamental phonon transport mechanisms, and suggest that 3C-SiC is an excellent wide-bandgap semiconductor for applications of next-generation power electronics as both active components and substrates.

Suggested Citation

  • Zhe Cheng & Jianbo Liang & Keisuke Kawamura & Hao Zhou & Hidetoshi Asamura & Hiroki Uratani & Janak Tiwari & Samuel Graham & Yutaka Ohno & Yasuyoshi Nagai & Tianli Feng & Naoteru Shigekawa & David G. , 2022. "High thermal conductivity in wafer-scale cubic silicon carbide crystals," Nature Communications, Nature, vol. 13(1), pages 1-9, December.
    • Handle: RePEc:nat:natcom:v:13:y:2022:i:1:d:10.1038_s41467-022-34943-w
    DOI: 10.1038/s41467-022-34943-w
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    References listed on IDEAS

    as
    1. Zhe Cheng & Ruiyang Li & Xingxu Yan & Glenn Jernigan & Jingjing Shi & Michael E. Liao & Nicholas J. Hines & Chaitanya A. Gadre & Juan Carlos Idrobo & Eungkyu Lee & Karl D. Hobart & Mark S. Goorsky & X, 2021. "Experimental observation of localized interfacial phonon modes," Nature Communications, Nature, vol. 12(1), pages 1-10, December.
    2. Daisuke Nakamura & Itaru Gunjishima & Satoshi Yamaguchi & Tadashi Ito & Atsuto Okamoto & Hiroyuki Kondo & Shoichi Onda & Kazumasa Takatori, 2004. "Ultrahigh-quality silicon carbide single crystals," Nature, Nature, vol. 430(7003), pages 1009-1012, August.
    3. William F. Koehl & Bob B. Buckley & F. Joseph Heremans & Greg Calusine & David D. Awschalom, 2011. "Room temperature coherent control of defect spin qubits in silicon carbide," Nature, Nature, vol. 479(7371), pages 84-87, November.
    4. R. B. Wilson & David G. Cahill, 2014. "Anisotropic failure of Fourier theory in time-domain thermoreflectance experiments," Nature Communications, Nature, vol. 5(1), pages 1-11, December.
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