COMPRESSIBLE FLOW in front of AN AXISYMMETRIC BLUNT OBJECT: ANALYTIC APPROXIMATION and ASTROPHYSICAL IMPLICATIONS

Uri Keshet; Yossi Naor

doi:10.3847/0004-637X/830/2/147

COMPRESSIBLE FLOW in front of AN AXISYMMETRIC BLUNT OBJECT: ANALYTIC APPROXIMATION and ASTROPHYSICAL IMPLICATIONS

Uri Keshet, Yossi Naor

Department of Physics

Ben-Gurion University of the Negev

Research output: Contribution to journal › Article › peer-review

Abstract

Compressible flows around blunt objects have diverse applications, but current analytic treatments are inaccurate and limited to narrow parameter regimes. We show that the gas-dynamic flow in front of an axisymmetric blunt body is accurately derived analytically using a low order expansion of the perpendicular gradients in terms of the parallel velocity. This reproduces both subsonic and supersonic flows measured and simulated for a sphere, including the transonic regime and the bow shock properties. Some astrophysical implications are outlined, in particular for planets in the solar wind and for clumps and bubbles in the intergalactic medium. The bow shock standoff distance normalized by the obstacle curvature is ∼2/(3g) in the strong shock limit, where g is the compression ratio. For a subsonic Mach number M approaching unity, the thickness δ of an initially weak, draped magnetic layer is a few times larger than in the incompressible limit, with amplification ∼(1 + 1.3M^2.6)/ (3σ).

Original language	American English
Article number	147
Journal	Astrophysical Journal
Volume	830
Issue number	2
DOIs	https://doi.org/10.3847/0004-637X/830/2/147
State	Published - 20 Oct 2016

Keywords

hydrodynamics
intergalactic medium
interplanetary medium
methods: analytical
shock waves

All Science Journal Classification (ASJC) codes

Astronomy and Astrophysics
Space and Planetary Science

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10.3847/0004-637X/830/2/147

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title = "COMPRESSIBLE FLOW in front of AN AXISYMMETRIC BLUNT OBJECT: ANALYTIC APPROXIMATION and ASTROPHYSICAL IMPLICATIONS",

abstract = "Compressible flows around blunt objects have diverse applications, but current analytic treatments are inaccurate and limited to narrow parameter regimes. We show that the gas-dynamic flow in front of an axisymmetric blunt body is accurately derived analytically using a low order expansion of the perpendicular gradients in terms of the parallel velocity. This reproduces both subsonic and supersonic flows measured and simulated for a sphere, including the transonic regime and the bow shock properties. Some astrophysical implications are outlined, in particular for planets in the solar wind and for clumps and bubbles in the intergalactic medium. The bow shock standoff distance normalized by the obstacle curvature is ∼2/(3g) in the strong shock limit, where g is the compression ratio. For a subsonic Mach number M approaching unity, the thickness δ of an initially weak, draped magnetic layer is a few times larger than in the incompressible limit, with amplification ∼(1 + 1.3M2.6)/ (3σ).",

keywords = "hydrodynamics, intergalactic medium, interplanetary medium, methods: analytical, shock waves",

author = "Uri Keshet and Yossi Naor",

note = "Funding Information: This research has received funding from the European Union Seventh Framework Programme (FP7/2007-2013) under grant agreement no 293975, from an IAEC-UPBC joint research foundation grant, from an ISF-UGC grant, and from an individual ISF grant. Publisher Copyright: {\"i}¿½ 2016. The American Astronomical Society. All rights reserved.",

year = "2016",

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doi = "10.3847/0004-637X/830/2/147",

language = "American English",

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AU - Naor, Yossi

N1 - Funding Information: This research has received funding from the European Union Seventh Framework Programme (FP7/2007-2013) under grant agreement no 293975, from an IAEC-UPBC joint research foundation grant, from an ISF-UGC grant, and from an individual ISF grant. Publisher Copyright: ï¿½ 2016. The American Astronomical Society. All rights reserved.

PY - 2016/10/20

Y1 - 2016/10/20

N2 - Compressible flows around blunt objects have diverse applications, but current analytic treatments are inaccurate and limited to narrow parameter regimes. We show that the gas-dynamic flow in front of an axisymmetric blunt body is accurately derived analytically using a low order expansion of the perpendicular gradients in terms of the parallel velocity. This reproduces both subsonic and supersonic flows measured and simulated for a sphere, including the transonic regime and the bow shock properties. Some astrophysical implications are outlined, in particular for planets in the solar wind and for clumps and bubbles in the intergalactic medium. The bow shock standoff distance normalized by the obstacle curvature is ∼2/(3g) in the strong shock limit, where g is the compression ratio. For a subsonic Mach number M approaching unity, the thickness δ of an initially weak, draped magnetic layer is a few times larger than in the incompressible limit, with amplification ∼(1 + 1.3M2.6)/ (3σ).

AB - Compressible flows around blunt objects have diverse applications, but current analytic treatments are inaccurate and limited to narrow parameter regimes. We show that the gas-dynamic flow in front of an axisymmetric blunt body is accurately derived analytically using a low order expansion of the perpendicular gradients in terms of the parallel velocity. This reproduces both subsonic and supersonic flows measured and simulated for a sphere, including the transonic regime and the bow shock properties. Some astrophysical implications are outlined, in particular for planets in the solar wind and for clumps and bubbles in the intergalactic medium. The bow shock standoff distance normalized by the obstacle curvature is ∼2/(3g) in the strong shock limit, where g is the compression ratio. For a subsonic Mach number M approaching unity, the thickness δ of an initially weak, draped magnetic layer is a few times larger than in the incompressible limit, with amplification ∼(1 + 1.3M2.6)/ (3σ).

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KW - interplanetary medium

KW - methods: analytical

KW - shock waves

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ER -

COMPRESSIBLE FLOW in front of AN AXISYMMETRIC BLUNT OBJECT: ANALYTIC APPROXIMATION and ASTROPHYSICAL IMPLICATIONS

Abstract

Keywords

All Science Journal Classification (ASJC) codes

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