FN Archimer Export Format PT J TI Head-on collisions between two quasi-geostrophic hetons in a continuously stratified fluid BT AF REINAUD, Jean N. CARTON, Xavier AS 1:1;2:2; FF 1:;2:; C1 Univ St Andrews, Math Inst, St Andrews KY16 9SS, Fife, Scotland. UBO UEB, UFR Sci, Lab Phys Oceans, F-29200 Brest, France. C2 UNIV ST ANDREWS, UK UBO, FRANCE UM LOPS IF 2.514 TC 5 UR https://archimer.ifremer.fr/doc/00277/38796/37470.pdf LA English DT Article DE ;geophysical and geological flows;quasi-geostrophic flows;vortex dynamics AB We examine the interactions between two three-dimensional quasi-geostrophic hetons. The hetons are initially translating towards one another. We address the effect of the vertical distance between the two poles (vortices) constituting each heton on the interaction. We also examine the influence of the horizontal separation between the poles within each heton. In this investigation, the two hetons are facing each other. Two configurations are possible depending on the respective locations of the like-signed poles of the hetons. When they lie at the same depth, we refer to the configuration as symmetric; the antisymmetric configuration corresponds to opposite-signed poles at the same depth. The first step in the investigation uses point vortices to represent the poles of the hetons. This approach allows us to rapidly browse the parameter space and to estimate the possible heton trajectories. For a symmetric pair, the hetons either reverse their trajectory or recombine and escape perpendicularly depending of their horizontal and vertical offsets. On the other hand, antisymmetric hetons recombine and escape perpendicularly as same-depth dipoles. In a second part, we focus on finite core hetons (with finite volume poles). These hetons can deform and may be sensitive to horizontal-shear-induced deformations, or to baroclinic instability. These destabilisations depend on the vertical and horizontal offsets between the various poles, as well as on their width-to-height aspect ratios. They can modify the volume of the poles via vortex merger, breaking and/or shearing out; they compete with the advective evolution observed for singular (point) vortices. Importantly, hetons can break down or reconfigure before they can drift away as expected from a point vortex approach. Thus, a large variety of behaviours is observed in the parameter space. Finally, we briefly illustrate the behaviour of tall hetons which can be unstable to an azimuthal mode l = 1 when many vertical modes of deformation are present on the heton. PY 2015 PD SEP SO Journal Of Fluid Mechanics SN 0022-1120 PU Cambridge Univ Press VL 779 UT 000359648700008 BP 144 EP 180 DI 10.1017/jfm.2015.422 ID 38796 ER EF