A theoretical study of the structural, elastic and electronic properties of spinel LiTi2O4 anode has been performed by density functional theory (DFT) plane-wave pseudopotential method. The independent elastic constants, shear modulus (G), bulk modulus (B), and Young's modulus (E) are evaluated, respectively. The results suggest that cubic LiTi2O4 is mechanically stable. The G/B ratio of 0.584 indicates the ductility of LiTi2O4 is good. The electron density difference of LiTi2O4 shows that the O-2p orbits overlap effectively with Ti-3d ones, confirming the formations of strong covalent bonds between them, while Li is fully ionized in the lattice. The formation enthalpy for LiTi2O4 is calculated to be -2070.723 +/- 1.6 kJ mol(-1). The strong covalent bonds between O and Ti atoms are not only responsible for the excellent mechanical stabilities but also very crucial for the thermodynamic stability of LiTi2O4 compound. Furthermore, in LiTi2O4 compound, the full occupation of 16(c) sites by Li+ not only leads to a smaller C-12 value but also leads to a much larger C-44 one. Therefore, the plasticity and ductility of the LiTi2O4 become poor in comparison to LiTi2O4, while the thermodynamic stability of LiTi2O4 can be further improved after the Li+ intercalation of LiTi2O4. (C) 2011 Elsevier B.V. All rights reserved.