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Theoretical investigation of the bow shock location for the solar wind interacting with the unmagnetized planet

Martian bow shocks, the solar wind interacting with an unmagnetized planet, are studied. We theoretically investigated how solar parameters, such as the solar wind dynamic pressure and the solar extreme ultraviolet (EUV) flux, influence the bow shock location, which is still currently not well understood. We present the formula for the location of the bow shock nose of the unmagnetized planet. The bow shock location, the sum of the ionopause location and bow shock standoff distance, is calculated in the gasdynamics approach. The ionopause location is determined using thermal pressure continuity, i.e., the solar wind thermal pressure equal to the ionospheric pressure, according to tangential discontinuity. The analytical formula of the ionopause nose location and the ionopause profile around the nose are obtained. The standoff distance is calculated using the empirical model. Our derived formula shows that the shock nose location is a function of the scale height of ionosphere, the dynamic pressure of the solar wind and the peak ionospheric pressure. The theoretical model implies that the shock nose location is more sensitive to the solar EUV flux than solar wind dynamics pressure. Further, we theoretically show that the bow shock location is proportional to the solar wind dynamic pressure to the power of negative C, where C is about the ratio of the ionospheric scale height to the distance between bow shock nose and the planet center. This theory matches the gasdynamics simulation and is consistent with the spacecraft measurement result by Mars Express [Hall, et al. (2016) J. Geophys. Res. Space Physics, 121, 11,474-11,494].