The Triple Dusk-Dawn Aberration of the Solar Wind at Earth

In this Brief Report it is pointed out that there are three dusk-dawn aberrations of the solar-wind plasma and magnetic structure approaching Earth and the magnitudes of these aberrations are estimated for various solar-wind types monitored from L1. Solar-wind monitors closer to the Earth than L1 would have superior performances.

The solar-wind plasma and its magnetic structure that hit an L1 monitor on the Sun-Earth line will on average pass duskward of the Earth’s magnetosphere. This is depicted in Figure 1 with L1 at the top of the sketch and with the shape of the magnetosphere drawn in blue using the Lin et al. (2010) magnetopause model (eq. (3) of Lin et al. (2010) with r_o = 10.8 R_E, m = 0.1, and β = −1.1).

FIGURE 1

FIGURE 1. A sketch of a net duskward aberration (red arrow) from a monitor at L1 (green).

The solar-wind velocity vector at 1 AU varies with time by about ±5° in both the dawn-dusk and north-south directions (cf. Borovsky 2012; Borovsky, 2018). With L1 being 235 R_E upstream from the Earth (cf. Figure 1), the ±5° time variation of the flow vector corresponds to a ±20.5 R_E time variation in the location at Earth of a flow streamline passing through an L1 monitor. The timescales of these velocity-vector changes can be slow (e.g., the days-long variations about stream interfaces discussed below) or fast [e.g., the 98 km/s change in the solar-wind velocity vector over 3 s shown in Fig. 6b of Borovsky (2020a)].

In addition to this variation in the streamline location at Earth, there is a systematic triple aberration (shift) in the dawn-dusk direction. The plasma flow of the solar wind experiences the first two aberrations and the magnetic structure of the solar wind experiences all three aberrations. The origins of the triple aberration are as follows.

(1) The motion of the Earth around the Sun. The 29.8 km/s dawnward motion of the Earth in its orbit (black arrow in Figure 1) means that for a perfectly radial solar-wind flow with a speed v_sw hitting L1 at the Sun-Earth line will have a streamline that passes the Earth on the dusk side by a distance of (235 R_E) (29.8/v_sw) (e.g., Fairfield, 1993). For v_sw = 350 km/s this distance is 20 R_E and for v_sw = 650 km/s this distance is 10.8 R_E (cf. Table 1). In Borovsky (2018) the variability of this first aberration owing to the variability of the solar-wind flow vector is examined in comparison with the typical structure sizes of the solar wind magnetic field (10’s of R_E to 100 R_E): cf. Fig. 5 of Borovsky (2018).

(2) The non-radial average flow vector of the solar wind. Using multiple spacecraft at 1 AU, Nemecek et al., (2020a) found a systematic nonradial component to the proton-solar-wind flow that tends to be in the direction of the solar rotation [see also Pizzo et al., (1983) and Finlay et al., (2019)]. As noted in Table 1, this systematic flow is ∼10 km/s dawnward for slow solar wind and is ∼5 km/s duskward for mid-range solar-wind speed. Note that there are also very large ∼40 km/s dawn-dusk flows at Earth associated with stream interfaces (Gosling et al., 1978): for slow-to-fast (leading-edge) stream interfaces the solar-wind flow is strongly dawnward on the day before the interface passes the Earth and the flow is strongly duskward on the day after the passage of the interface [cf. Fig. 4b of Borovsky and Denton (2010)] and for fast-to-slow (trailing-edge) stream interfaces the solar-wind flow is systematically duskward for about 3 days prior to the interface passage and the flow is systematically dawnward for about 3 days after the interface passage [cf. Fig. 14b of Borovsky and Denton (2016)]. As noted in Table 1, the Nemecek et al., (2020a) 10 km/s dawnward velocity in a 350 km/s wind yields an offset of 6.7 R_E for the streamline at Earth.

(3) The magnetic structure of the heliosphere moves out from the Sun along the Parker spiral faster than the proton flow. In the Alfvenic fast wind and in the Alfvenic slow wind, the magnetic structure of the heliosphere moves outward from the Sun at a speed of about 0.7 v_A along the Parker-spiral direction relative to the proton flow (Borovsky, 2020b; Nemecek et al., 2020b). [Alfvénic wind has strong temporal correlations between the flow vector v(t) and the magnetic-field vector B(t).] A nominal 45° Parker-spiral orientation is sketched as the green arrow in Figure 1. For v_sw in the range 500–650 km/s, the mean Alfven speed in the OMNI2 data set (King and Papitashvili, 2005) is v_A = 73 km/s. Accounting for the angle of the Parker spiral from the Sun-Earth line (39° for 500 km/s and 32° for 650 km/s) the aberration of the magnetic structure is estimated to be 31.7 km/s duskward for 500 km/s Alfvenic solar wind and 27.1 km/s for 650 km/s Alfvenic solar wind (cf. Table 1). These aberrations yield “streamline” duskward displacements of 14.9 R_E and 9.8 R_E. Note that the alpha particles of the solar wind are approximately at rest in the reference frame moving with the magnetic structure (Nemecek et al., 2020b), so the alpha-particle flow has the same aberration as the magnetic structure. Also note that at 1 AU the instantaneous magnetic-field direction varies by about ±45° with respect to the calculated Parker-spiral direction [cf. Table 1 of Borovsky (2010)], but the magnetic structure moves in the mean-field direction which is the calculated Parker-spiral direction.

TABLE 1

TABLE 1. Estimates of the dusk-dawn aberrations of the proton plasma and the magnetic structure for typical solar wind types.

These aberrations are on the order of the 10s-of-R_E magnetic structure sizes in the background Parker-spiral solar wind at 1 AU (Borovsky, 2008; 2018).

Assuming a radial proton flow, the magnitude of the first aberration is straightforward to calculate with the formula (29.8/v_sw): if the flow is not radial the correction to the first aberration is very small. The second aberration (caused by the non-radial flow) is very variable with time: with a ±5° variation in the flow vector this is a ∼ ±20-R_E variation at Earth. The variability of the third aberration has yet to be explored: the Parker-spiral direction varies according to the known formula (405/v_sw) however the statistics of the magnetic-structure velocity vector with respect to the Parker-spiral direction have not been studied.

The aberration problem from L1 gets better or worse depending on the location of the solar-wind monitor about the L1 point. And during the systematic large deflections of the solar wind in the days around the passages of stream interfaces, the aberration problem gets worse.

There have been a number of recent criticisms of using L1 monitoring for solar-wind/magnetosphere coupling studies (Sandahl et al., 1996; Ashour-Abdalla et al., 2008; Borovsky, 2018, 2020a; Walsh et al., 2019; Burkholder et al., 2020) and several estimates of the solar-wind errors between L1 and Earth (Crooker et al., 1982; Ridley, 2000; Weimer et al., 2002; Mailyan et al., 2008; Case and Wild, 2012). These criticisms and error calculations were based on the temporal flow deviations of the solar wind, the magnetic-structure scalesizes in the solar wind, and cross correlations between L1 measurements and near-Earth measurements.

In studying the driving of the Earth by the solar wind, recent work indicates that errors in the solar-wind values make it difficult to uncover or confirm the physics of the driving. In particular in data-analysis studies the “best fit” formulas obtained by optimizing correlations change depend on the amount of noise in the solar wind measurements (Borovsky, 2022; Sivadas et al., 2022).

To make needed progress in understanding solar-wind/magnetosphere interaction, a call is made for solar-wind monitors much closer to the Earth than L1. A study to optimize the monitor mission is needed. One suggestion would be multiple spacecraft in IMP-type circular orbits (r ∼ 30 R_E) wherein one of the spacecraft would always be in the upstream solar wind.

Data Availability Statement

The original contributions presented in the study are included in the article/Supplementary Material, further inquiries can be directed to the corresponding author.

Author Contributions

The author confirms being the sole contributor of this work and has approved it for publication.

Funding

JEB was supported by the NSF GEM Program via grant AGS-2027569 and by the NASA HERMES Interdisciplinary Science Program via grant 80NSSC21K1406.

Conflict of Interest

The author declares that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Publisher’s Note

All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article, or claim that may be made by its manufacturer, is not guaranteed or endorsed by the publisher.

Acknowledgments

The author thanks Bob McPherron, Zdenek Nemecek, and Nithin Sivadas for helpful conversations.

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