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Ultrahigh thermal conductivity in isotope-enriched cubic boron nitride.

Ke ChenBai SongNavaneetha K RavichandranQiye ZhengXi ChenHwijong LeeHaoran SunSheng LiGeethal Amila Gamage Udalamatta GamageFei TianZhiwei DingQichen SongAkash RaiHanlin WuPawan KoiralaAaron J SchmidtKenji WatanabeBing LvZhifeng RenLi ShiDavid G CahillTakashi TaniguchiDavid BroidoGang Chen
Published in: Science (New York, N.Y.) (2020)
Materials with high thermal conductivity (κ) are of technological importance and fundamental interest. We grew cubic boron nitride (cBN) crystals with controlled abundance of boron isotopes and measured κ greater than 1600 watts per meter-kelvin at room temperature in samples with enriched 10B or 11B. In comparison, we found that the isotope enhancement of κ is considerably lower for boron phosphide and boron arsenide as the identical isotopic mass disorder becomes increasingly invisible to phonons. The ultrahigh κ in conjunction with its wide bandgap (6.2 electron volts) makes cBN a promising material for microelectronics thermal management, high-power electronics, and optoelectronics applications.
Keyphrases
  • room temperature
  • quantum dots
  • ionic liquid
  • reduced graphene oxide
  • gold nanoparticles
  • mass spectrometry
  • wastewater treatment