Dimensionless Numbers

Definition: $Pr=\nu /\alpha$ , where $\nu$ is the viscosity, and $\alpha$ is the thermal diffusivity.
Interpretation: The ratio between the momentum diffusivity (i.e. viscosity) and heat diffusivity.
Analysis: The typical Prandtl number for water is around 7 for water (At 20 degrees Celsius). See also Schmidt number.

Definition: $Re={\frac {UL}{\nu }}$ , where $U$ and $L$ are the characteristic velocity and length scales, and $\nu$ is the dynamic viscosity.
Interpretation: The ratio of inertial force to viscous force.
Analysis: Small Reynolds numbers are often associated with viscous flows, whereas large Reynolds numbers are typically found in turbulent flows.

Definition: $Ri=N^{2}/U_{z}^{2}$ , where $N$ is the buoyancy frequency and $U$ is the background horizontal velocity.
Interpretation: The ratio between the strength of stratification and velocity shear.
Analysis: A sufficient condition for the flow to be linearly stable is that the local Richardson number exceed 0.25 throughout the flow. However, $Ri<0.25$ does not mean the flow is necessarily unstable (the criterion is not sufficient). When the flow is not a parallel shear flow, the meaning of $Ri$ is not clear.

Definition: $Sc=\nu /\kappa$ , where $\nu$ is the viscosity, and $\kappa$ is the mass diffusivity.
Interpretation: The ratio between the momentum diffusivity (i.e. viscosity) and mass diffusivity.
Analysis: The typical Schmidt number for water is around 500, depending on the temperature and salinity. For direct numerical simulations, $Sc=1$ is commonly used in the literature. See also Prandtl number.

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