Abstract
The subsonic, compressible, potential flow around a hypersphere can be derived using the Janzen–Rayleigh expansion (JRE) of the flow potential in even powers of the incident Mach number ${\mathcal {M}}_\infty$ . JREs were carried out with terms polynomial in the inverse radius $r^{-1}$ to high orders in two dimensions, but were limited to order ${\mathcal {M}}_\infty ^{4}$ in three dimensions. We derive general JRE formulae for arbitrary order, adiabatic index and dimension. We find that powers of $\ln (r)$ can creep into the expansion, and are essential in the three-dimensional (3-D) sphere beyond order ${\mathcal {M}}_\infty ^{4}$ . Such terms are apparently absent in the 2-D disk, as we verify up to order ${\mathcal {M}}_\infty ^{100}$ , although they do appear in other dimensions (e.g. at order ${\mathcal {M}}_\infty ^{2}$ in four dimensions). An exploration of various 2-D and 3-D bodies suggests a topological connection, with logarithmic terms emerging when the flow is simply connected. Our results have additional physical implications. They are used to improve the hodograph-based approximation for the flow in front of a sphere. The symmetry-axis velocity profiles of axisymmetric flows around different prolate spheroids are approximately related to each other by a simple, Mach-independent scaling.
Highlights
While ideal flows are an extreme limit, they play an important role in research, for example (i) as a basis for more realistic flows, with additional effects such as viscosity; (ii) for modelling the bulk of weakly interacting Bose–Einstein condensate superfluids, which can be approximated as an inviscid, compressible fluid with a polytropic index γ = 2; (iii) for modelling flow regimes which are not sensitive to the level of weak viscosity, such as in front of a round object; and (iv) for code validation and pedagogical reasons. 932 A6-1I.S
The Janzen–Rayleigh expansion (JRE) has been generalized to several areas of research, such as vortex flows (e.g. Barsony-Nagy, Er-El & Yungster 1987; Heister et al 1990; Moore & Pullin 1991, 1998; Meiron, Moore & Pullin 2000; Leppington 2006; Crowdy & Krishnamurthy 2018), porous channel flows (Majdalani 2007; Maicke & Majdalani 2008, 2010; Cecil, Majdalani & Batterson 2015), and acoustics (Slimon, Soteriou & Davis 2000; Moon 2013) and could be used in a wide range of other applications, as we demonstrate below
The resulting, arbitrary-order JRE is a useful tool for studying various problems, as we demonstrate by generalizing and extending previous solutions for the axial flow of a
Summary
The two-dimensional (2-D) flow around a disk has been researched extensively (Janzen 1913; Rayleigh 1916; Van Dyke & Guttmann 1983; Guttmann & Thompson 1993), for example in search for a solution to the transonic controversy, namely, ‘the existence, or non-existence, of a continuous transonic flow, that is, without a shock wave, around a symmetrical wing profile, with zero incidence with respect to the undisturbed velocity’ (Ferrari 1966) These and other problems that require a high-order expansion could not be explored as thoroughly in the 3-D case, because previous JREs for the sphere were limited to second, i.e. M4∞, order (Kaplan 1940; Tamada 1940). Sections §§ 6 and 7 demonstrate some applications of the JRE, and can be skipped if the reader is uninterested in the hodograph and prolate approximations
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