Abstract The interaction among ENSO, large-scale circulation and tropical storm (TS) activity over the western North Pacific is investigated through three-dimensional eddy energetics and ECHAM4.6 T106 high resolution numerical experiments. The results show that the TS formation regions shift southeastward associated with the southeastward extension and intensification of monsoon trough and low-level westerly when the July to September Ni?o3.4 SST is increased (warm ENSO years). Both the eddy barotropic energy conversion at low-levels and eddy baroclinic energy conversion at high-levels enhance and extend eastward from the Philippine Sea (130°-150°E) to the date line. The enhanced barotropic and baroclinic energy conversion is mainly related to the cyclonic anomaly, eastward extension of westerly jet and anomalous ascending motion associated with warm SST anomaly over the tropical central-eastern Pacific. These anomalous large-scale environments and the barotropic energy conversion as well as the baroclinic energy conversion are favorable for the southward extension of TS formation region. The anomalous cold SST, anticyclonic anomaly and anomalous descending motion appear over the subtropical and mid-latitude western North Pacific during warm years. These large-scale circulations are not beneficial for the barotropic energy conversion in this region. The enhanced baroclinic energy conversion plays an important role in maintaining and strengthening the subsequent development of tropical storms as they propagate into north of 20°N over the western North Pacific. The loss of EAPE to EKE due to the baroclinic energy conversion is supplemented by both the EAPE generation through eddy diabatic heating and MAPE to EAPE conversion associated with the vertical heat transport of eddies, which is excluded in two-dimensional EAPE budget equation. These eddy energetic results suggested that the large-scale circulations and corresponding eddy barotropic energy conversion mainly contribute to the southeastward shift of TS genesis region. The tropical transient eddies including tropical storms may be self-development and intensify through their diabatic heating and baroclinic processes. To clarify the active and passive roles between ENSO-related SST, large-scale circulation and eddy energy process, three numerical experiments using the ECHAM4.6 T106 high resolution model are performed. The ECHAM4 control experiment, force by observed SST globally, reproduces the interannual variations of large-scale circulation, TS formation and TS frequency east of 140°E as in observation. The results of numerical experiments support that warm SST forcing over the equatorial central-eastern Pacific plays an active role in setting the favorable large-scale environments for the formation and early-development of transient eddy including TS over the western North Pacific. The equatorial central-eastern Pacific heating generates significant cyclonic anomaly and strong westerly that enhanced the eddy barotropic and baroclinic energy conversion for the growth of transient eddies including TSs. However, the cooling effect over the equatorial western Pacific would weaken the amplitudes of low-level cyclonic anomaly and westerly jet induced by warm SST anomaly over the equatorial central-eastern Pacific. The ECHAM4 T106 significantly underestimates the intensity of TS which might be resulted from the insufficient resolution. This discrepancy would restrain the strengthening of transient eddy including TS through self development process and in turn reduce the interaction between transient eddies and large-scale circulation in model. A sufficient high resolution and/or an air-sea coupled model might improve the simulations of eddy diabatic heating and its impact on the TS intensity, track and large-scale environments.