Abstract
Abstract Tropical cyclones that evolve from a nontropical origin and undergo tropical transition (TT) play a prominent role in cyclogenesis in the North Atlantic Ocean. They pose a special challenge for predictions, as they often emerge at the end of a multiscale cascade of atmospheric processes. Here we use operational European Centre for Medium-Range Weather Forecasts ensemble predictions to investigate the TT of North Atlantic Hurricane Chris (2012), whose formation was preceded by the merger of two potential vorticity (PV) maxima, eventually resulting in the cyclone-inducing PV streamer. The principal goal is to elucidate the dynamic and thermodynamic processes governing the predictability of Chris’s cyclogenesis and subsequent TT. Dynamic time warping is applied to identify ensemble tracks that are similar to the analysis track. This technique permits small temporal and spatial shifts in the development. The formation of the pre-Chris cyclone is predicted by those members that also predict the merging of the two PV maxima. The PV streamer’s shape and its position relative to the pre-Chris cyclone determine whether the cyclone follows the TT pathway. The transitioning cyclones are located inside a favorable region of high equivalent potential temperatures that result from a warm seclusion underneath the cyclonic roll-up of the PV streamer. A systematic investigation of consecutive ensemble forecasts indicates that sudden changes in ensemble statistics of cyclone metrics are linked to specific events. The present case exemplifies how a novel combination of Eulerian and cyclone-relative ensemble forecast analysis tools allow inference of physical causes of abrupt changes in predictability.
Highlights
Tropical transition (TT) describes the phenomenon when a tropical cyclone (TC) emerges from an extratropical cyclone (Davis and Bosart 2003, 2004)
Hurricane Chris was chosen for this multiscale predictability study because of the complex antecedent potential vorticity (PV) dynamics and the strong baroclinic environment in the upper and lower levels that facilitated the development of the extratropical precursor cyclone
North Atlantic Hurricane Chris (2012) was chosen because of the complex antecedent PV dynamics and the strong baroclinic environment in the upper and lower levels that facilitated the development of the extratropical precursor cyclone
Summary
Tropical transition (TT) describes the phenomenon when a tropical cyclone (TC) emerges from an extratropical cyclone (Davis and Bosart 2003, 2004). A cascade of events commonly precedes the TT: anticyclonic wave breaking (e.g., Thorncroft et al 1993; Postel and Hitchman 1999) causes an upperlevel precursor potential vorticity (PV) trough to penetrate into the (sub)tropics (Galarneau et al 2015), which initially induces the development of either an antecedent extratropical (Davis and Bosart 2004) or subtropical cyclone (Evans and Guishard 2009; González-Alemán et al 2015; Bentley et al 2016, 2017). The convection associated with the precursor cyclone eventually diminishes the PV gradients above the cyclone center and, reduces vertical wind shear (Davis and Bosart 2003, 2004), providing a favorable environment for the cyclone to acquire tropical nature
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