Effect of solar wind density and velocity on the subsolar standoff distance of the Martian magnetic pileup boundary

Wang, M.; Lee, L. C.; Xie, Luhua; Xu, Xiaokang; Lu, J. Y.; Кабин, К.; Wang, J.; Li, L.; Sui, H. Y.

doi:10.1051/0004-6361/202140511

Cited by 11 publications

(35 citation statements)

References 53 publications

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“…However, in their observational study, it was hard to remove the influence of other factors completely, such as the IMF and the crustal field. Recently, using a 3D multispecies MHD model, Wang et al (2021) confirmed the power-law relation between the subsolar standoff distance of the Martian MPB and P d . They further indicated that for the same P d , a higher solar wind velocity (lower density) can result in a larger subsolar standoff distance, which is explained by the stronger magnetic pileup process.…”

Section: Introductionmentioning

confidence: 81%

“…They further indicated that for the same P d , a higher solar wind velocity (lower density) can result in a larger subsolar standoff distance, which is explained by the stronger magnetic pileup process. However, Wang et al (2021) only focused on the subsolar point of the Martian MPB, and did not study the dependence of the whole geometry of the Martian MPB on the individual solar wind density and velocity.…”

Section: Introductionmentioning

confidence: 99%

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A 3D parametric Martian magnetic pileup boundary model with the effects of solar wind density, velocity, and IMF

Wang

Sui

Lü

et al. 2022

A&A

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Using global magnetohydrodynamic simulations, we construct a 3D parametric model of the Martian magnetic pileup boundary (MPB). This model employs a modified parabola function defined by four parameters. The effects of the solar wind dynamic pressure, the solar wind densities and velocities, and the intensity and orientation of the interplanetary magnetic field (IMF) are examined using 267 simulation cases. The results from our parametric model show that (1) the MPB moves closer to Mars when the upstream solar wind dynamic pressure (Pd) increases, the subsolar standoff distance decreases and the flaring degree of the Martian MPB increases with an increasing Pd according to the power-law relations. For the same Pd, a higher solar wind velocity (a lower density) leads to a farther location of the MPB from Mars, along with a larger flaring degree, which is explained by the higher solar wind convection electric fields and a stronger magnetic pileup process under these conditions. (2) Larger Y or Z components of the IMF, BY or BZ, result in a thicker pileup region and a farther MPB location from Mars, as well as a decrease in the flaring degree. The radial IMF component, BX, has little effect on the geometry of the MPB. (3) In most of the simulations used to derive the current parametric model, the strongest Martian crustal magnetic field is located on the dayside. However, for a larger value of the southward IMF, the Martian MPB is located farther away in the northern hemisphere instead of the southern hemisphere. The north-south asymmetry of the Martian MPB with the southern hemisphere being farther away is observed for other IMF directions. We suggest that the magnetic reconnection of the southward IMF with the crustal field that occurs at middle latitudes of the southern hemisphere results in different magnetic field topologies and the closer location of the MPB under these conditions. Our model results show a relatively good agreement with the previous empirical and theoretical models.

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Section: Introductionmentioning

confidence: 81%

Section: Introductionmentioning

confidence: 99%

A 3D parametric Martian magnetic pileup boundary model with the effects of solar wind density, velocity, and IMF

Wang

Sui

Lü

et al. 2022

A&A

Self Cite

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“…, where P t is the thermal pressure, P b = B 2 /2μ 0 is the magnetic pressure, P d = ρv 2 is the dynamic pressure and MB denotes the magnetic barrier. Different methods give different IMB standoff distances (Wang et al 2021). Based on magnetic pressure, Zhang et al (1991) defined the upper boundary as the position where the local magnetic pressure equals half of the upstream solar wind dynamic pressure adjusted for the normal angle of the barrier,…”

Section: The Scale Of the Induced Magnetospherementioning

confidence: 99%

The Dependence of the Venusian Induced Magnetosphere on the Interplanetary Magnetic Field: An MHD Study

Zuo

et al. 2022

ApJ

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The influences of the interplanetary magnetic field (IMF) on the induced magnetosphere of Venus are investigated using a global multispecies magnetohydrodynamics (MHD) model. The simulation results show that the induced magnetosphere is controlled by the IMF components perpendicular to the solar wind velocity (B Y and B Z in the Venus Solar Orbital coordinate), rather than the IMF magnitude (∣B∣). With the increase of ( B Y 2 + B Z 2 ) 1 2 , the induced magnetosphere becomes stronger in field strength and thicker in spatial scale, and the bow shock locates farther from the planet. The parallel IMF component (B X ) has relatively small impacts on the magnetic barrier and the magnetotail, regardless of the various IMF magnitudes and orientations caused by different B X . The responses of the Venusian induced magnetosphere to the change of upstream IMF are also studied. The time-dependent MHD calculations show that the dayside magnetosphere responds quickly with a timescale of 10 s–10 minutes, depending on the considered magnetospheric region. For comparison, the timescale required for the adjustment of magnetotail as driven by an IMF rotation is derived to be ∼10–20 minutes.

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“…Importantly, however, no strong consensus yet exists regarding the physical parameters that specifically delineate the MPB. It has variously been defined as a pressure‐balance surface (Girazian et al., 2019; Holmberg et al., 2019), or by gradients in plasma and field pressures (Wang et al., 2021), and is also at least often well correlated with changes in the plasma composition from solar wind (H + ) to planetary ions (O + ,

{\mathrm{O}}_{2}^{+}

) dominated regimes (hence the occasionally used name, ion composition boundary, ICB; Halekas et al., 2018). Comparing these different definitions, it should be noted that the differences in location and behavior remain generally small compared to the intrinsic variability of the location of the MPB with upstream conditions.…”

Section: Introductionmentioning

confidence: 99%

A Two‐Spacecraft Study of Mars' Induced Magnetosphere's Response to Upstream Conditions

et al. 2022

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Mars has no intrinsic dipolar magnetic field with which to stand off the incoming solar wind. Instead its conducting ionosphere acts as an effective obstacle to the incoming solar wind and an induced magnetosphere is formed, the structure of which is determined for instance by the solar wind input, ultraviolet (UV) radiation, the Martian crustal magnetic fields and the underlying neutral atmosphere (Bertucci et al., 2011;Nagy et al., 2004). Many aspects of the Mars-solar wind interaction are outwardly comparable to those at Venus, as was extensively studied during the Pioneer-Venus era, and thus much of the understanding developed initially for Venus can be transferred to the Mars interaction, despite differences of scale, solar wind conditions, and so on (Luhmann & Cravens, 1991). Moreover, the Mars-solar wind interaction has been extensively studied in recent years by ESA's Mars Express (MEX) and NASA's Mars Atmosphere and Volatile EvolutioN (MAVEN) missions, and relevant aspects are summarized below.The Mars-solar wind interaction is typically characterized by the formation of several distinct plasma boundaries separating regions of differing plasma properties and compositions. At the largest distances, the bow shock is formed upstream from the planet, inside which the solar wind is slowed, heated and deflected around the

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Effect of solar wind density and velocity on the subsolar standoff distance of the Martian magnetic pileup boundary

Cited by 11 publications

References 53 publications

A 3D parametric Martian magnetic pileup boundary model with the effects of solar wind density, velocity, and IMF

A 3D parametric Martian magnetic pileup boundary model with the effects of solar wind density, velocity, and IMF

The Dependence of the Venusian Induced Magnetosphere on the Interplanetary Magnetic Field: An MHD Study

A Two‐Spacecraft Study of Mars' Induced Magnetosphere's Response to Upstream Conditions

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