With the increasing demand in structural and electronic characterizations at high spatial resolution, atomically-resolved scanning transmission electron microscope (STEM) has become an indispensable tool in modern materials research. When used in combination with electron energy-loss spectroscopy (EELS) that reflects the electronic features of unoccupied density of states, a simultaneous tackling of the structural and electronic characters at atomic resolution had been proven possible and this conjunct STEM-EELS technique is most suitable for addressing the physics at a reduced dimension. In this thesis, we report on such a STEM-EELS application in unveiling the microscopic physics across the RNiO3/SrTiO3 heterointerfaces (R = La, Pr, and Nd; RNiO3 thickness, 10 unit cells for all three heterostructural systems). The nickelates are well-known to display a metal-to-insulator transition, with the characteristic transition temperature being an intricate function of the given structural distortion, and all the three materials are metallic at room temperature in the bulk state. While the LaNiO3/SrTiO3 preserves the signature metallicity at room temperature, the PrNiO3/SrTiO3 and NdNiO3/SrTiO3 unexpectedly turn out to be insulating. A thorough structural characterization revealed that the structural distortion in the PrNiO3 and NdNiO3 films are noticeably large compared to the characteristic magnitude in the respective bulks. More surprisingly, all three heterointerfaces manifest a positive charge density (~1014/cm2), at odds with the conventional wisdom that an insulating interface is not supposed to display a residual charge density. The corresponding structure-property correlations were discussed in this work.