Abstract
Abstract This study focuses on the rainfall-producing weather systems in the southern Murray–Darling Basin (MDB), Australia. These weather systems are divided into objects: cyclones, fronts, anticyclones, warm conveyor belt (WCB) inflows, WCB ascents, potential vorticity (PV) streamers, and cutoff lows. We investigate the changes in the frequency, amplitude, and relative position of these objects as the daily and seasonal rainfall change. Days on which the rainfall is heavy, especially in winter, are characterized by more PV streamers, cutoff lows, cyclones, fronts, and WCBs in the region. In contrast, dry days are characterized by more anticyclones over southeastern Australia in winter and summer. The effect of upper-level weather objects (PV streamers and cutoff lows) on lower-level objects, and their importance in producing rainfall, is quantified using the quasigeostrophic ω equation and separating the vertical motion into that induced by the upper and lower levels. On heavy rainfall days in winter, PV streamers and cutoff lows force strong upward motion in the lower troposphere, promoting cyclogenesis at lower levels, forcing ascent in the WCBs, and producing rain downstream of the southern MDB. Lower-level ascent forced by upper-level objects is important for the development of heavy rainfall in both seasons, although particularly in winter. Rainfall is attributed to individual objects. PV streamers and WCBs contribute most to the winter and summer rainfall, respectively. The difference in rainfall between anomalously wet and dry years can be explained in winter by the changes in the rainfall associated with PV streamers, whereas in summer it is mostly due to a reduction in the rainfall associated with WCBs. Significance Statement The aim of the present study is to better understand how synoptic-scale weather systems differ in southeastern Australia in dry and wet periods, by considering a wide range of weather systems. We found weather systems are more closely aligned in the vertical on heavy rainfall days, and the majority of rainfall in this region is associated with warm conveyor belts. These results point to warm conveyor belts being an important, but not well recognized, contributor to rainfall in this region. Future work may investigate the roles of the various modes of variability and climate change in modulating warm conveyor belts and hence the regional rainfall variability in Australia.
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