Direct Numerical Simulations of K-type transition in a flat-plate boundary layer with supercritical fluids

We investigate the controlled K-type breakdown of a flat-plate boundary-layer with highly non-ideal supercritical fluid at a reduced pressure of \(p_{r,\infty}=1.10\). Direct numerical simulations are performed at a Mach number of \(M_\infty=0.2\) for one subcritical (liquid-like regime) temperature profile and one strongly-stratified transcritical (pseudo-boiling) temperature profile with slightly heated wall. In the subcritical case, the formation of aligned \(\Lambda\)-vortices is delayed compared to the reference ideal-gas case of Sayadi et al. (J. Fluid Mech., vol. 724, 2013, pp. 480-509), with steady longitudinal modes dominating the late-transitional stage. When the wall temperature exceeds the pseudo-boiling temperature, streak secondary instabilities lead to the simultaneous development of additional hairpin vortices and near-wall streaky structures near the legs of the primary aligned \(\Lambda\)-vortices. Nonetheless, transition to turbulence is not violent and is significantly delayed compared to the subcritical regime.