Why is it necessary to consider both buoyancy and momentum in Δh?

• A. Only buoyancy matters.
• B. Delta h is unrelated to plume rise.
• C. Only momentum matters.
• D. Both mechanisms contribute to how high the plume rises; momentum from exit velocity and buoyancy from temperature difference can compound.

Answer: (D)

The height a plume reaches (Δh) comes from two driving forces, and they work together. Momentum from the exit velocity gives the plume an initial push upward, helping it rise through the surrounding air before buoyancy can act strongly. Buoyancy comes from the temperature (and density) difference between the plume and ambient air, providing a continuous lift as the plume rises and entrains surrounding air. When both are present, they can compound—the fast exit velocity gets the plume off the ground and into a region where buoyancy can keep driving it upward, often producing a higher Δh than either mechanism would alone. In practice, plume-rise models often add the momentum-driven and buoyancy-driven contributions to estimate the total rise.