In a planetary magnetosphere, the bow shock is the boundary at which the solar wind abruptly drops as a result of its approach to the magnetopause. The best-studied example of a bow shock is that occurring where the solar wind encounters the Earth's magnetopause, although bow shocks occur around all planets. The Earth's bow shock is about 100-1000 km thick and located about 90,000 km from the Earth.

The defining criterion is that the bulk velocity of the fluid (in this case, the solar wind) drops from "supersonic" to "subsonic", where the speed of sound in plasma physics is defined as

$c\_s^2\; =\; \backslash gamma\; p/\; \backslash rho$

where c_s is the speed of sound, $\backslash gamma$ is the ratio of specific heats, p is the pressure, and $\backslash rho$ is the density of the plasma.

The particles making up the solar wind follow spiral paths along magnetic field lines. The velocity of each particle as it gyrates around a field line can be treated similarly to a thermal velocity in an ordinary gas, and in an ordinary gas, the mean thermal velocity is roughly the speed of sound. At the bow shock, the bulk forward velocity of the wind (which can be seen as the velocity of the points on the field lines about which the particles gyrate) drops below the speed at which the particles are corkscrewing.

It is hypothesised that the Sun also has a bow shock as it travels through the interstellar medium, as shown in the figure. This will occur if the interstellar medium is moving supersonically towards the sun. Thus, the interstellar medium is moving supersonically towards the sun, while the sun's solar wind is moving supersonically away from the sun. The point where the interstellar medium becomes subsonic is the bow shock; the point where the interstellar medium and solar wind pressures balance is at the heliopause; the point where the solar wind becomes subsonic is the termination shock. According to Robert Nemiroff and Jerry Bonnell of NASA, the solar bow shock may lie at around 230 AU from the Sun.

Bow shocks are also a common feature in Herbig Haro objects, in which a much stronger collimated outflow of gas and dust from the star interacts with the stellar medium, producing bright bow shocks that are visible at optical wavelengths.

See also

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• Shock Wave

External links

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• Bow shock image (BZ Cam)
• Bow shock image (IRS8)
• Bow shock image (HD77581)
• Bow shock image (LL Ori)
• Good diagram from a research paper on shocks
• More on the Voyagers

References

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Kivelson MG, Russell CT. 1995. Introduction to Space Physics . Cambridge University Press. (p. 129)

Cravens, TE. 1997. Physics of Solar System Plasmas. Cambridge University Press. (p. 142)

Bow shock | 뱃머리 충격파