Electrochemical batteries are believed to be a key technology to decarbonize transportation and electricity supply. Here, we investigate germanium which has been shown to be a promising anode material for Na ion as well as Li ion batteries. Compared to Si, Ge provides higher ionic diffusivities and more stable insertion sites for Li/Na/Mg as well as isotropic expansion. It is well established that Li doping of Si results in interstitial Li defects. This is apparently also true for Na insertion. Mg impurities in Ge were previously attributed to substitutional defects. This suggests that Ge may possess more favorable insertion energetics for substitutional defects than for interstitial. This is important for potential use of Ge in electrochemical batteries, as it would strongly affect both voltages and rate capability, as voltage is directly related to defect formation (insertion) energy, and rate capability directly related to diffusion barriers which are defect type dependent.
We present a comparative computational study of the insertion and diffusion of Li, Na, and Mg in Ge at different concentrations at substitutional and interstitial sites. We find that, depending on the concentration, the most stable configurations for Li, Na, and Mg insertion can consist of tetrahedral sites, substitutional sites, or a combination of the two types of sites. This is an important finding, as most of the previous ab initio studies of alloying type electrode materials ignored substitutional sites. The defect formation energies computed at dilute concentration (x = 1/64) show that Na and Mg insertion are not thermodynamically favored in Ge vs formation of bulk Na and Mg, as opposed to Li insertion which is favored. We show that a larger mechanical stress generated by Na and Mg insertion, compared to Li insertion, contributes to the high energy cost of insertion. We investigate the effect of p doping of Ge (with Ga) on the thermodynamics and find that it considerably lowers the defect formation energies associated with the insertion of Li/Na/Mg at tetrahedral sites. On the other hand, the energetics associated with Li/Na/Mg insertion at substitutional sites are not significantly affected. In addition, we compute the migration energy barriers for Li/Na/Mg diffusion between two tetrahedral sites (0.38/0.79/0.66 eV), between two substitutional sites (1.11/1.20/2.14 eV), and between two sites of different type (2.15/1.78/0.85 eV).