TY - EJOU AU - Turkyilmazoglu, Mustafa AU - Alotaibi, Abdulaziz TI - Sharp Interface Establishment through Slippery Fluid in Steady Exchange Flows under Stratification T2 - Computer Modeling in Engineering \& Sciences PY - 2025 VL - 143 IS - 3 SN - 1526-1506 AB - The variable salinity in stored reservoirs connected by a long channel attracts the attention of scientists worldwide, having applications in environmental and geophysical engineering. This study explores the impact of Navier slip conditions on exchange flows within a long channel connecting two large reservoirs of differing salinity. These horizontal density gradients drive the flow. We modify the recent one-dimensional theory, developed to avoid runaway stratification, to account for the presence of uniform slip walls. By adjusting the parameters of the horizontal density gradient based on the slip factor, we resolve analytically various flow regimes ranging from high diffusion to transitional high advection. These regimes are governed by physical parameters like channel aspect ratio, slip factor, Schmidt number, and gravitational Reynolds number. Our solutions align perfectly with ones in the no-slip limit. More importantly, under the conditions of no net flow across the channel and high Schmidt number (where stratification is concentrated near the channel’s mid-layer), we derive a closed-form solution for the slip parameter, aspect ratio, and gravitational Reynolds number that describes the interface’s behavior as a sharp interface separating two distinct zones. This interface, arising from hydrostatic wall gradients, ultimately detaches the low- and high-density regimes throughout the channel when the gravitational Reynolds number is inversely proportional to the aspect ratio for a fixed slip parameter. This phenomenon, observed previously in 2D numerical simulations with no-slip walls in the literature, is thus confirmed by our theoretical results. Our findings further demonstrate that wall slip leads to distinct and diverse flow regimes. KW - Stratification; density gradient; exchange flow; wall slip; sharp interface DO - 10.32604/cmes.2025.068031