Anisotropic ferromagnetism in carbon doped zinc oxide from first-principles studies

Abstract

A density functional theory study of substitutional carbon impurities in ZnO has been performed, using both the generalized gradient approximation (GGA) and a hybrid functional (HSE06) as exchange-correlation functional. It is found that the non-spinpolarized CZn impurity is under almost all conditions thermodynamically more stable than the CO impurity which has a magnetic moment of 2μB, with the exception of very O-poor and C-rich conditions. This explains the experimental difficulties in sample preparation in order to realize d0-ferromagnetism in C-doped ZnO. From GGA calculations with large 96-atom supercells, we conclude that two CO-CO impurities in ZnO interact ferromagnetically, but the interaction is found to be short-ranged and anisotropic, much stronger within the hexagonal ab-plane of wurtzite ZnO than along the c-axis. This layered ferromagnetism is attributed to the anisotropy of the dispersion of carbon impurity bands near the Fermi level for CO impurities in ZnO. From the calculated results, we derive that a CO concentration between 2% and 6% should be optimal to achieve d0-ferromagnetism in C-doped ZnO.