This study investigates a subtropical oceanic mesoscale convective vortex (MCV) that occurred from 1800 UTC 4 June to 1200 UTC 6 June 2008 during Intensive Observing Period (IOP) 6 of the Southwest Monsoon Experiment (SoWMEX) and the Terrain-influenced Monsoon Rainfall Experiment (TiMREX). The dense observations over Taiwan, the Taiwan Strait and South China Sea are using to examine the kinematics and thermodynamic structure of the MCV. High resolution simulation through the Advanced Research Weather Research and Forecasting Model (ARW) are adopted to reveal the cyclogenesis and the overall evolution. During 4-5 June 2008, a Meiyu front accompanied with a nearly barotropic vorticity strip across the middle Taiwan through the southern Taiwan Strait which formed as a southwesterly low-level jet developed to the south of subsiding easterly flow. The vertical wind shear between 500-925 hPa was weak, and yet the deep wind shear reached 18 m s-1 between 200-850 hPa. A mesoscale convective system (MCS) developed rapidly after 1800 UTC 4 June. The high-tropospheric difffluence was presented. An eastward tilted MCV was revealed on the northern edge of the MCS with a horizontal scale of 200 km and the depth of 6 km. In the vicinity of the MCV center, the atmosphere possessed conditional and potential instability. The moist front flank and gradually drying rear flank resulted in the asymmetric precipitation. The cool pool was observed beneath the heavy precipitation. The mid-tropospheric mesolow cohered with higher-level warn core. An inner sub-vortex, on a scale of 25–30 km with maximum shear vorticity of 3x10-3 s-1, embedded in the stronger convection line. The simulated vortex has similar structure compared with the observation. The incipient convection initialed within the ambient vorticity. In the vicinity area, there were colder boundary layer, moist mid-tropospheric air, medium convective available potential energy and low level of free convection. The vortical hot towels were cohered with individual convective cells. The convective updraft maintain by latent heating. The vorticity analyses show the vorticity strengthened upward and downward from 750 hPa. The altitude of maximum vorticity decreased to the near boundary layer. Stretching effect was the principal contribution of cyclogensis, tilting effect provided the positive contribution in the mid-troposphere. Nevertheless, the dry rear inflow penetrated into the MCV not only suppressed staitifrom precipitation but also inhibited convection in the upshear direction. Beside, the intensifying vertical wind shear in the higher troposphere limited the vortex vertical extent to about 6 km. The subtropical oceanic MCV did not further grow into a Typhoon.