This thesis studies the slowdown of typhoon motion by the asymmetric typhoon (TY) structure for typhoons classified as the tracks 2 and 3 by Central Weather Bureau (CWB). Specifically, we study the post-landfall TY motion slowdown of Morakot (2009), Fanapi (2010), and Haitang (2005). Satellite and radar data indicate that these TYs are with significant asymmetric convection structure in the post-landfall period. In particular, the post-landfall speed of TY Morakot is 5 km h-1, which is much slower than the environmental deep-level mean flow speed of 10 km h-1. Since the post-landfall speed of these TYs are slower than that before, our hypothesis is that the asymmetric convection structure to the southeast of the TY, induced by the interaction of TC circulation with topography of Taiwan or southwesterly monsoon flow, may generate wavenumber 1 (WN1) potential vorticity (PV) tendency to slowdown the northwestward moving storm. We use Cloud-Resolving Storm Simulator (CReSS) with analysis data for the Year of Tropical Convection from European Centre for Medium-Range Weather Forecasts (ECMWF-YOTC) or from National Center for Environmental Prediction (NCEP) to simulate the three TYs. The CReSS model produces rainfall and track simulations that are in general agreement with observations. With PV tendency diagnosis, we investigate the impact of convection and latent heating effect on the storm motion slowdown for the three TY cases. The diagnosis suggests that the asymmetric convection indeed contributes to the WN1 PV tendency and leads to the slowdown of TY motion. In addition, we perform the water vapor sensitivity experiments to substantiate the importance of the water vapor supply in the asymmetric convection and latent heating. By reducing water vapor content in the period immediately after TY’s departure from Taiwan, the model experiments with less water vapor are with faster TY motion. The PV diagnosis of the water vapor reduction experiments indicates the decrease of the latent heating effect and the WN1 PV tendency leads to the increase of TY motion. Our research highlights the importance of the asymmetric convection structure on the TY motion in the post-landfall period. The asymmetric convection in general may be caused by the interaction of TY circulation with Taiwan topography or southwesterly monsoon flow. The PV diagnosis is effective in identifying the contributing factors for the TY motion.