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Facile diamond synthesis from lower diamondoids.

Sulgiye ParkIwnetim I AbateBy Jin LiuChenxu WangJeremy E P DahlRobert M K CarlsonLiuxiang YangVitali B PrakapenkaEran GreenbergThomas Peter DevereauxChunjing JiaRodney C EwingWendy L MaoYu Lin
Published in: Science advances (2020)
Carbon-based nanomaterials have exceptional properties that make them attractive for a variety of technological applications. Here, we report on the use of diamondoids (diamond-like, saturated hydrocarbons) as promising precursors for laser-induced high-pressure, high-temperature diamond synthesis. The lowest pressure and temperature (P-T) conditions that yielded diamond were 12 GPa (at ~2000 K) and 900 K (at ~20 GPa), respectively. This represents a substantially reduced transformation barrier compared with diamond synthesis from conventional (hydro)carbon allotropes, owing to the similarities in the structure and full sp3 hybridization of diamondoids and bulk diamond. At 20 GPa, diamondoid-to-diamond conversion occurs rapidly within <19 μs. Molecular dynamics simulations indicate that once dehydrogenated, the remaining diamondoid carbon cages reconstruct themselves into diamond-like structures at high P-T. This study is the first successful mapping of the P-T conditions and onset timing of the diamondoid-to-diamond conversion and elucidates the physical and chemical factors that facilitate diamond synthesis.
Keyphrases
  • molecular dynamics simulations
  • high resolution
  • mental health
  • high temperature
  • mass spectrometry