Theoretical study of novel B–C–O compounds with non-diamond isoelectronic

Two novel non-isoelectronic with diamond(non-IED)B–C–O phases(tI16-B₈C₆O₂and mP16-B₈C₅O₃)have been unmasked.The research of the phonon scattering spectra and the independent elastic constants under ambient pressure(AP)and high pressure(HP)proves the stability of these non-IED B–C–O phases.Respective to the common compounds,the research of the formation enthalpies and the relationship with pressure of all non-IED B–C–O phases suggests that HP technology performed in the diamond anvil cell(DAC)or large volume press(LVP)is an important technology for synthesis.Both tI16-B₈C₆O₂and tI12-B₆C₄O₂possess electrical conductivity.mP16-B₈C₅O₃is a small bandgap semiconductor with a 0.530 eV gap.For aP13-B₆C₂O₅,mC20-B₂CO₂and tI18-B₄CO₄are all large gap semiconductors with gaps of 5.643 eV,6.113 eV,and 7.105 eV,respectively.The study on the relationship between band gap values and pressure of these six non-IED B–C–O phases states that tI16-B₈C₆O₂and tI12-B₆C₄O₂maintain electrical conductivity,mC20-B₂CO₂and tI18-B₄CO₄have good bandgap stability and are less affected by pressure.The stress-strain simulation reveals that the max strain and stress of 0.4 GPa and 141.9 GPa respectively,can be sustained by tI16-B₈C₆O₂.Studies on their mechanical properties shows that they all possess elasticity moduli and hard character.And pressure has an obvious effect on their mechanical properties,therein toughness of tI12-B₆C₄O₂,aP13-B₆C₂O₅,mC20-B₂CO₂and tI18-B4CO4 all increases,and hardness of mP16-B₈C₅O₃continue to strengthen during the compression.With abundant hardness characteristics and tunable band gaps,extensive attention will be focused on the scientific research of non-IED B–C–O compounds.