We carry out first-principles and tight-binding calculations to study the electronic properties of low-dimensional materials. First, we have two negatively charged low-dimensional systems, single-walled carbon nanotubes and monolayer graphene. Through calculating the band structure and the charge density with different supercells, we show that some nearly free electron states are artificial states in negatively charged systems. Furthermore, we also reveal that although there are two types of states both looking like nearly free electron states, their origin and properties are totally different. Our results suggest that in first-principles more careful calculations should be implemented in negatively charged low-dimensional systems. Then, we focus on another interesting material, twisted bilayer graphene. We construct maximally-localized Wannier functions for a twist angle 5.08◦ twisted bilayer graphene. By applying tight-binding scheme, we further study two intriguing properties of twisted bilayer graphene: renormalization Fermi velocity and charge density localization. In contrast to previous studies, we show that the charge density localization of twisted bilayer graphene is not in the AA region in general. Furthermore, even though both the Fermi velocity and charge density localization fluctuate with respect with different twist angles, these two fascinating properties are not correlated. This suggests that these two phenomena are originated from different mechanisms.