The Rankine vortex is a fundamental mathematical model in fluid dynamics that approximates the structure of a vortex in a viscous, incompressible fluid, featuring a central core of solid-body rotation surrounded by an outer irrotational flowregion.[1] In this model, the tangential velocity increases linearly with radius within the core (r < a), reaching a maximum at the core boundary, and then decreases inversely with radius in the exterior (r ≥ a), ensuring continuity of velocity but a discontinuity in the velocity gradient at the interface.[1] The vorticity is uniform and constant inside the core, equal to twice the angular velocity, while it vanishes outside, making the model analytically tractable for studying idealized vortex behavior.[2]Named after the Scottish engineer and physicist William John Macquorn Rankine (1820–1872), who contributed significantly to thermodynamics and hydrodynamics, the model was developed as part of early efforts to describe steady rotational flows in fluids.[3] Mathematically, in cylindrical coordinates with no radial or axial velocity components, the azimuthal velocity v_\theta is given by v_\theta = \Omega r for r < a (where \Omega is the constant angular velocity) and v_\theta = \Omega a^2 / r for r \geq a, with the circulation \Gamma = 2\pi \Omega a^2 conserved throughout.[1] This piecewise formulation simplifies calculations of pressure distributions and free-surface deformations, such as in bathtub drains, where the surface depression follows z = -\frac{\Omega^2 a^4}{2gr^2} outside the core under gravity.[1] Although idealized—ignoring viscosity's smoothing effects at the core edge—the model captures essential features like maximum tangential speed at the core radius and zero vorticity far from the center.[2]The Rankine vortex serves as a baseline for analyzing more complex atmospheric and oceanic phenomena, including tornadoes, dust devils, and mesocyclones, where core radii range from tens to thousands of meters and tangential speeds exceed 10 m/s.[2] In hurricane modeling, it approximates the primary circulation with modifications for asymmetry and radial decay, aiding in wind profile predictions and risk assessment for storm surges and structural damage.[4] Extensions like the modified Rankine vortex incorporate exponential decay beyond a cutoff radius to better fit observed tropical cyclone data, enhancing parametric representations in numerical weather prediction.[5] Its simplicity facilitates analytical studies of vortex stability, wave propagation, and interactions with boundaries, remaining a cornerstone in engineering applications such as vortex suppressors in intakes and turbine designs.
Overview
Definition
The Rankine vortex is a simplified mathematical model representing steady, axisymmetric vortex flow in an inviscid fluid, characterized by a composite structure that merges an inner forced vortex region of solid-body rotation with an outer free vortex region of irrotational flow.[6] This two-zone idealized model provides a conceptual framework for understanding vortex dynamics by delineating a central core where fluid elements rotate rigidly and an enveloping region where angular momentum is conserved without rotation.[7]Named after the Scottish engineer and physicist William John Macquorn Rankine (1820–1872), the model serves as an approximation for the steady-state structure of vortices in viscous fluids, capturing essential features like a defined rotational core surrounded by potential flow.[7] Key parameters defining the Rankine vortex include the core radius a, which demarcates the boundary between the inner and outer regions; the circulation strength \Gamma, representing the total circulation around the vortex; and the uniform angular velocity \Omega = \frac{\Gamma}{2\pi a^2} within the core.[8]
Historical Development
The Rankine vortex model originated in the mid-19th century as part of William John Macquorn Rankine's contributions to hydrodynamics. In his 1858 publication A Manual of Applied Mechanics, Rankine introduced the model as a simplified representation of rotational flow, featuring a central region of solid-body rotation enveloped by an outer irrotational region, to aid in understanding steady vortex structures in inviscid fluids. This formulation built on Rankine's broader work in applied mechanics, where he sought to provide practical mathematical tools for engineers studying fluid motion.The development of the Rankine vortex occurred amid rapid progress in 19th-century fluid mechanics, particularly influenced by contemporary theories of vortex motion. Hermann von Helmholtz's 1858 theorems established the conservation of vortex strength (circulation) in barotropic, inviscid flows, providing a foundational framework for analyzing discrete vortices without dissipation. Similarly, William Thomson (later Lord Kelvin) advanced vortex dynamics through his 1867 investigations into persistent vortex rings in ether, drawing parallels to atomic structures and emphasizing the stability of rotational flows in ideal fluids. Rankine's model complemented these ideas by offering an explicit, analytically tractable example of a combined vortex suitable for pedagogical and engineering applications.A key milestone came in 1880 when Lord Kelvin extended the model's utility by deriving the linearized inviscid oscillations of the Rankine vortex, interpreting them within his vortex atom theory to explore wave propagation along columnar vortices. This analysis highlighted the model's capacity to support neutral stability modes, influencing subsequent studies on vortex stability.By the 20th century, the Rankine vortex had evolved into a standard pedagogical tool in fluid dynamics literature, valued for its simplicity in demonstrating core-outer flow transitions. It featured prominently in texts like David J. Acheson's Elementary Fluid Dynamics (1990), which employs the model to teach ideal rotational flows and circulation concepts. Today, it remains a cornerstone in aerodynamics and meteorology textbooks, facilitating the approximation of real-world vortices such as those in aircraft wakes and tropical cyclones.[7]
Mathematical Formulation
Velocity Profile
The Rankine vortex model assumes steady, axisymmetric, incompressible flow in cylindrical coordinates (r, \theta, z), with zero radial velocity (v_r = 0) and zero axial velocity (v_z = 0), such that the velocity field consists solely of the tangential component v_\theta(r).[9] This setup represents an idealized vortex combining rotational and irrotational regions without viscous effects in the inviscid limit.The tangential velocity profile is piecewise defined, reflecting solid-body rotation in the core and potential flow outside. For the inner core region where r \leq a (with a denoting the core radius), v_\theta(r) = \Omega r = \frac{\Gamma}{2\pi a^2} r, where \Omega is the constant angular speed and \Gamma is the circulation around the vortex.[9] This linear dependence on radius characterizes rigid rotation within the core.[2]In the outer region where r > a, the flow is irrotational, yielding v_\theta(r) = \frac{\Gamma}{2\pi r}, analogous to a free vortex with circulation conserved along streamlines.[9] The profile ensures tangential continuity at the interface r = a, where the maximum tangential speed occurs as v_{\max} = \frac{\Gamma}{2\pi a}.[2]This velocity field can be derived from the Euler equations for steady, axisymmetric, inviscid flow, where the radial momentum balance \frac{v_\theta^2}{r} = -\frac{1}{\rho} \frac{\partial p}{\partial r} (with \rho the constant density) integrates to yield the piecewise form under assumptions of constant vorticity inside the core and zero vorticity outside.[9] Alternatively, using the stream function \psi for axisymmetric flow, the azimuthal velocity satisfies v_\theta = -\frac{1}{r} \frac{\partial \psi}{\partial r}, leading to \psi \propto r^2 in the core (linear v_\theta) and \psi \propto \ln r outside (inverse v_\theta), with matching at r = a to preserve continuity.[9]
Vorticity Distribution
The vorticity \vec{\omega} of a fluidflow is defined as the curl of the velocity field, \vec{\omega} = \nabla \times \vec{v}.[10] In the case of the Rankine vortex, which assumes axisymmetric flow in cylindrical coordinates (r, \theta, z) with velocity components \vec{v} = (0, v_\theta(r), 0), the vorticity is purely axial, and the dominant component is \omega_z = \frac{1}{r} \frac{\partial (r v_\theta)}{\partial r}.[11] This axial vorticity characterizes the rotational nature of the flow.Within the inner core region where r \leq a (with a denoting the core radius), the vorticity \omega_z is constant and uniform, given by \omega_z = 2\Omega = \frac{\Gamma}{\pi a^2}, where \Omega is the constant angular velocity of the solid-body rotation and \Gamma is the circulation of the vortex.[10] This uniform distribution implies rigid rotation throughout the core, analogous to a rotating solid cylinder.[11] In contrast, for the outer region where r > a, the flow is irrotational, and \omega_z = 0.[10] This zero vorticity outside the core models the potential flow far from the vortex axis.The circulation \Gamma around any closed path encircling the vortex axis is conserved and equals \Gamma = \oint \vec{v} \cdot d\vec{l} = 2\pi a v_{\max}, where v_{\max} is the maximum tangential velocity at r = a.[11] By Stokes' theorem, \Gamma = \iint (\nabla \times \vec{v}) \cdot d\vec{A}, this circulation directly relates to the integrated vorticity over the core area, confirming \Gamma = \pi a^2 \omega_z.[10]The vorticity distribution is derived by computing the curl in cylindrical coordinates using the piecewisevelocity profile of the Rankine vortex. Inside the core, the linear v_\theta yields \frac{1}{r} \frac{\partial (r v_\theta)}{\partial r} = 2\Omega, while outside, the inverse-r dependence gives zero.[11] This results in a discontinuity in \omega_z at the boundary r = a, which serves as a physical approximation for real vortices where vorticity gradients are sharp but smoothed by viscosity.[10]
Physical Properties
Core Region Dynamics
In the core region of the Rankine vortex, the flow undergoes solid-body rotation, where every fluid particle rotates with a constant angular velocity \Omega, resulting in no relative motion between particles within the core of radius a. This rigid rotation is characterized by a tangential velocity v_\theta = \Omega r, which increases linearly with the radial distance r from the center.[12][13]The kinetic energy density in this core region increases quadratically with radius, given by \frac{1}{2} \rho v_\theta^2 = \frac{1}{2} \rho \Omega^2 r^2, where \rho is the fluid density. This distribution reflects the accumulation of rotational energy toward the periphery of the core, contributing to the overall stability of the vortex structure. Centrifugal effects arising from this rotation are balanced by radial pressure gradients in the steady-state condition, preventing radial expansion or contraction of the core.[12]The model idealizes the core as requiring infinite viscosity or continuous external forcing to sustain the uniform solid-body rotation, in contrast to real vortex cores where viscous diffusion leads to smoother velocity gradients. At the boundary r = a, the tangential velocity matches that of the outer irrotational flow, ensuring continuity across the interface. This setup, as originally formulated, provides a foundational representation of concentrated vorticity in inviscid approximations.[13][14]
Pressure and Streamlines
In the Rankine vortex model, the radial distribution of pressure is derived from the steady, inviscid Euler equations under the assumption of axisymmetric flow with negligible radial and axial velocity components. The radial momentum balance, known as the cyclostrophic approximation, yields the equation\frac{\partial p}{\partial r} = \rho \frac{v_\theta^2}{r},where p(r) is the static pressure, \rho is the fluiddensity (assumed constant), and v_\theta(r) is the azimuthal velocity.[9] This equation expresses the balance between the radial pressure gradient and the centrifugal force due to rotation. To obtain the pressure profile, the equation is integrated radially from the vortex core outward to the far field, where p(r \to \infty) = p_\infty, the ambient pressure at infinity.[9]In the outer region (r \geq a), the flow is irrotational with v_\theta(r) = \frac{\Gamma}{2\pi r}, where \Gamma is the circulation and a is the core radius. Substituting this velocity profile into the radial momentum equation and integrating gives the pressure distributionp(r) = p_\infty - \frac{\rho \Gamma^2}{8\pi^2 r^2}, \quad r \geq a.This profile shows a pressure deficit that decays inversely with r^2, reflecting the weakening influence of the vortex far from the core.[9]In the inner core region (r \leq a), the flow undergoes solid-body rotation with constant angular velocity \Omega = \frac{\Gamma}{2\pi a^2}, so v_\theta(r) = \Omega r. The radial momentum equation then becomes \frac{\partial p}{\partial r} = \rho \Omega^2 r. Integrating from the center (r = 0) yieldsp(r) = p(0) + \frac{1}{2} \rho \Omega^2 r^2, \quad r \leq a.Continuity of pressure at the interface r = a with the outer profile determines the central pressure, which is the minimum in the vortex:p(0) = p_\infty - \frac{\rho \Gamma^2}{4\pi^2 a^2}.Thus, the full inner pressure profile isp(r) = p_\infty - \frac{\rho \Gamma^2}{4\pi^2 a^2} + \frac{1}{2} \rho \Omega^2 r^2, \quad r \leq a.This quadratic increase from the center balances the increasing centrifugal force within the rotating core.[9]The derivation relies on the principles of steady, inviscid flow captured by the Euler equations, which are equivalent to applying Bernoulli's equation along individual streamlines in this context, as the total head varies across streamlines due to vorticity in the core.[9]The streamlines in the Rankine vortex are purely azimuthal, consisting of concentric circular paths centered on the vortex axis in both the inner and outer regions. With no radial velocity (v_r = 0), there is no cross-streamline flow, resulting in closed, non-intersecting circular streamlines that follow the velocity field exactly.[9] This idealized pattern highlights the vortex's symmetry and lack of radial transport under the model's assumptions.
Applications and Comparisons
Meteorological and Aerodynamic Uses
In meteorology, the Rankine vortex model serves as a foundational approximation for simulating the structure of tornadoes and hurricanes, where the solid-body rotation in the core region effectively represents the intense eye-wall rotation observed in these phenomena.[15] This model is particularly useful in estimating wind speed distributions, aiding in the approximation of tornado intensities within frameworks like the Fujita scale by relating observed damage patterns to inferred vortex parameters. For hurricanes, parametric profiles based on the Rankine vortex have been employed in historical and stochastic risk assessments to describe radial wind profiles, providing a simple baseline for broader parametric hurricane models.[4][5]In aerodynamics, the Rankine vortex is applied to model tip vortices generated by aircraft wings, capturing the concentrated rotation in the vortex core that contributes to wake turbulence hazards.[16] This approximation supports predictions of vortex evolution and decay, informing Federal Aviation Administration (FAA) guidelines for aircraft separation standards to mitigate encounter risks during takeoff and landing.[17] Studies from the 1970s, including FAA flight tests on wake vortex effects from jet transports, evaluated hazard severity and contributed to establishing initial spacing rules for executive and general aviationaircraft.[18][19]Beyond these fields, the Rankine model facilitates laboratory simulations of bathtub vortices, where it approximates the tangential velocity profile in rotating container experiments to study free-surface flows and gas entrainment.[20] In turbomachinery design, it provides a simplified representation of swirling flows in cyclone separators, enabling initial estimates of particle separation efficiency through the forced vortex core and outer free vortex regions.[21] The model's mathematical simplicity allows for rapid parameter estimation, such as circulation strength derived from observed wind speeds, making it valuable for preliminary analyses across these applications.[22]
Limitations in Real Vortices
The Rankine vortex model idealizes a vortex with a sharp boundary separating a core of uniform vorticity from an outer irrotational region, assuming an inviscid fluid with no viscous diffusion. In reality, this abrupt transition is unphysical, as viscous effects cause vorticity to diffuse gradually, leading to smoother profiles such as the Gaussian distribution observed in the Lamb-Oseen vortex, which evolves from an initial concentrated vorticity through radial spreading over time.[23] The model's uniform corevorticity also overlooks the diffusive broadening of the coreradius, resulting in an overestimation of the vortex's sharpness and longevity in unsteady flows.[23]Real vortices, particularly in atmospheric contexts like tornadoes, often exhibit non-circular cores due to environmental influences such as wind shear, which introduces asymmetries not captured by the axisymmetric Rankine assumption. For instance, Doppler radar observations reveal elongated or tilted vortex structures influenced by vertical wind shear, deviating from the model's perfect rotational symmetry. Viscous effects further limit the model by ignoring the gradual decay of circulation through molecular diffusion and turbulent mixing, which smooths the core and reduces peak velocities more rapidly than the inviscid Rankine profile predicts.[24]Comparisons to more advanced models highlight these shortcomings; the Burgers vortex incorporates viscous diffusion and axial straining to sustain a steady core, representing a viscous counterpart to the Rankine model and better approximating confined flows with radial inflow. Similarly, the Sullivan vortex accounts for atmospheric buoyancy and secondary circulations, providing a more realistic outer flow structure for large-scale vortices like hurricanes, where the Rankine model's zero-viscosity limit fails to capture dissipative losses.[24][25]Empirically, while the Rankine model is sometimes fitted to Doppler radar data by adjusting the core radius to match observed tangential velocities, real pressure drops within tornado cores are often steeper than those derived from the model, indicating unaccounted-for dynamical effects like multiple subvortices or intensified convergence. This fitting approach thus serves as an approximation but underscores the need for modifications to align with observed asymmetries and viscous realities.[26]