Cubic boron nitride(c-BN)thin films were deposited on Si substrates by applying ion beam assisted deposition and then doped by S ion implantation.To produce a uniform depth profile of S ions in c-BN films,the implanta...Cubic boron nitride(c-BN)thin films were deposited on Si substrates by applying ion beam assisted deposition and then doped by S ion implantation.To produce a uniform depth profile of S ions in c-BN films,the implantation was carried out for the multiple energies.A slight degradation of c-BN crystallinity resulted from ion implantation can be recovered by thermal annealing,keeping the cubic phase content as high as 92%.The resistance reduces from 1010X for the as-deposited c-BN film to 108X after an S implantation of 5 9 1014ions cm-2and annealing at 1,173 K,suggesting an electrical doping effect of S dopant.The electrical resistance of the S-doped c-BN thin film decreases with increasing temperature,indicating semiconductor characteristics.The activation energy of S dopant is estimated to be 0.28±0.01 eV from the temperature dependence of resistance.展开更多
基金supported by the National Basic Research Program of China(2012CB619306)the National Natural Science Foundation of China(61376007)
文摘Cubic boron nitride(c-BN)thin films were deposited on Si substrates by applying ion beam assisted deposition and then doped by S ion implantation.To produce a uniform depth profile of S ions in c-BN films,the implantation was carried out for the multiple energies.A slight degradation of c-BN crystallinity resulted from ion implantation can be recovered by thermal annealing,keeping the cubic phase content as high as 92%.The resistance reduces from 1010X for the as-deposited c-BN film to 108X after an S implantation of 5 9 1014ions cm-2and annealing at 1,173 K,suggesting an electrical doping effect of S dopant.The electrical resistance of the S-doped c-BN thin film decreases with increasing temperature,indicating semiconductor characteristics.The activation energy of S dopant is estimated to be 0.28±0.01 eV from the temperature dependence of resistance.
