Statistics from 1999 Ji-Ji earthquake indicated that elementary and high school building structures were among the most seismically vulnerable of all, and the failure mechanism was found to be of a shear-type failure along the corridor without exception. This is a systematic problem of reinforced concrete structures worthwhile exploring. Conducting seismic capacity assessment on the existing RC structures and accordingly, selecting the cost-effective retrofit solutions is the policy currently adopted by the Construction and Planning Agency, Ministry of the Interior. Nevertheless, the current seismic capacity assessment methods are not providing reliable assessment. Therefore, the objective of this study is to explore the seismic behavior of typical RC structures for elementary schools using ATENA 2D. The results will be compared with those obtained by ETABS. ATENA 2D is based on the nonlinear stress-strain relationship (constitutive law) established from the fracture mechanics of reinforced concrete, it is more sound and reliable than ETABS, in which the inelastic behavior of the reinforced concrete is considered only by pre-defined plastic hinges at a certain localized positions. Simulation results indicate that the short-column effects caused by window stages lead to a shear-type failure and reduction of ductility of the reinforced concrete structures, as exactly revealed from many damaged elementary or high schools in Ji-Ji earthquake. The parametric study also indicates that the longitudinal reinforcement, either area-wise or size-wise, of a RC column affects both the ultimate shear capacity and ductility. In addition, the axial force in the RC column affects its nonlinear behavior and should not be ignored in the assessment. It is found that the short-column effect reduces ductility of the reinforced concrete structures while increasing its ultimate lateral strength. The existence of short columns is not necessarily detrimental to the overall seismic strength of the structures. This observation contradicts to what we used to recognize about short columns before. The results by ATENA in terms of the seismic capacity curves imply more conservative estimates of the ultimate strength and ductility of the RC structures than those by ETABS. The industry should be more cautious when using the ETABS-based pushover version of the “Seismic Capacity Assessment Method of RC Structures” for analysis to avoid overestimation on the seismic capacity of the structures and miss the chance for seismic retrofit.