Abstract
Magnetic reconnection is a universal process leading to energy conversion in plasmas1. It occurs in the Solar System2,3,4,5,6,7, in laboratory plasmas 8 and is important in astrophysics 9,10. Reconnection has been observed so far only at large-scale boundaries between different plasma environments 4,5,6,7,8. It is not known whether reconnection occurs and is important in turbulent plasmas where many small-scale boundaries can form. Solar11 and laboratory12 measurements as well as numerical simulations 13,14,15,16 indicate such possibility. Here we report, for the first time, in situ evidence of reconnection in a turbulent plasma. The turbulent environment is the solar wind downstream of the Earth’s bow shock. We show that reconnection is fast and electromagnetic energy is converted into heating and acceleration of particles. This has significant implications for laboratory and astrophysical plasmas where both turbulence and reconnection should be common.
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The Earth’s bow shock forms owing to the interaction of the Earth’s magnetosphere with the solar-wind flow17. The region downstream of the bow shock, the magnetosheath, is one of the most turbulent environments in the near-Earth space. The turbulence is stronger when the magnetic field in the solar wind is directed approximately along the shock normal, the so-called quasi-parallel shock18. Downstream of the quasi-parallel shock, large-amplitude fluctuations in density and magnetic field have been observed18 and thin current sheets are likely to form. Magnetic reconnection is easily initiated in thin current sheets19. Therefore, the magnetosheath is an ideal laboratory to study in situ magnetic reconnection in a turbulent plasma. Here we present, for the first time, in situ evidence of magnetic reconnection in a turbulent plasma using spacecraft observations in a thin current sheet found in the magnetosheath downstream of the quasi-parallel shock. We show that reconnection is important for heating and acceleration of particles in turbulent plasma.
We analyse four Cluster spacecraft20 data from 27 March 2002. Figure 1a shows the spacecraft orbit. The spacecraft separation for this event is about 100 km. Figure 1b shows a schematic diagram of how thin current sheets could be formed in the turbulent plasma downstream of the quasi-parallel shock, together with a schematic diagram of magnetic reconnection. Figure 2 shows an overview of plasma and magnetic-field observations. The spacecraft cross the bow shock around 09:35 universal time. Between 09:35 and 11:00, the spacecraft are in the magnetosheath downstream of the quasi-parallel shock, the angle between the interplanetary magnetic field and the normal to the shock is 10∘<θ<30∘. This highly turbulent region is characterized by substantial ion heating and acceleration, Fig. 2a, together with strong fluctuations both in the density, Fig. 2b, and in the magnitude of the magnetic field, Fig. 2c. The detailed properties of the turbulence for this region will be discussed in a separate publication (D.S., A.R., A.V. and S. D. Bale, manuscript in preparation). Around 11:00, the shock changes from quasi-parallel to quasi-perpendicular (θ>50∘), the fluctuations in density and magnetic field become smaller and the high-energy ions (>10 keV) disappear. Many thin current sheets with a typical width of a few ion inertial lengths, λi, are found in the magnetosheath downstream of the quasi-parallel shock during the time interval 09:45–10:50 but not downstream of the quasi-perpendicular shock. These observations indicate that the thin current sheets only form in the region with the strongest turbulence. As an example, Fig. 2d shows nine thin current sheets (colour shaded) over a 1.5 min interval. The current sheet around 10:16:52 (blue shaded) is analysed in detail in this paper to provide evidence of reconnection. Figure 3 shows four-spacecraft magnetic-field observations of the current sheet around 10:16:52. The magnetic-field components are plotted in the local current-sheet coordinate system NML. This coordinate system is obtained by combining the minimum variance analysis21 with multi-spacecraft timing22 of the magnetic field under the assumption of a stationary and planar current sheet moving at constant velocity, Vcs, along its normal direction, N. The multi-spacecraft timing gives Vcs≈200 km s−1. The duration of the current-sheet crossing 10:16:52.4–52.9 is 0.5 s, which corresponds to a current-sheet thickness in the normal direction of about 100 km≈1λi, obtained using Vcs. The four spacecraft all observe similar magnetic field during the current-sheet crossing, thus indicating that the current sheet is planar over the spacecraft separation ∼λi and time stationary on a timescale of ∼1 s, which is approximately one ion gyroperiod. Observations in Fig. 3 suggest that the spacecraft cross the current sheet during ongoing reconnection and very close to the X-line where reconnection is initiated, the so-called ion diffusion region. In the diffusion region, the electrons move together with the magnetic-field lines at the E×B/B2 velocity, whereas the ions do not, so that Hall magnetic field, BM, and electric field, EN, are created, as shown in the schematic diagram in Fig. 1b and expected from models and simulations19,23,24 and from previous observations7,8,25,26. Figure 3b shows that, for all of the spacecraft, the out-of-plane component, BM, has a bipolar signature consistent with Hall magnetic field, whereas the maximum variance component, BL, reverses across the current sheet, Fig. 3a, and the magnitude of the magnetic field, B, has a deep minimum in the centre, Fig. 3d. BN is slightly varying but on average negative, Fig. 3c, as is expected during reconnection and discussed below.
To provide evidence of magnetic reconnection, Fig. 4 shows combined observations of density and electric and magnetic fields for spacecraft 4. Magnetic reconnection is ongoing when there is an electric field at the X-line locally tangential to it23. Thus, for a two-dimensional geometry such as the one in Fig. 1b, the strongest evidence of reconnection is an electric field in the out-of-plane direction, Ecs,M<0, together with a normal magnetic field, . Ecs,M is an absolute measure of the reconnection rate. The tangential electric field, Ecs,M, measured in the current-sheet reference frame, Fig. 4f, is varying but on average Ecs,M≈−0.5 mV m−1. The condition Ecs,M<0 corresponds to plasma inflow towards the X-line from both sides of the current sheet at the velocity Vin=VE×B,N=(E×B/B2)N≃Ecs,M/BL≃25 km s−1 in the normal direction, see Fig. 4l where the vertical scale has been chosen so that this inflow can be clearly seen. In the centre of the current sheet, VE×B,N becomes very large reaching values of up to 200–300 km s−1 (not shown). This is consistent with conservation of the magnetic flux transported across the current sheet (when B gets small VE×B,N should increase) but it could also be due to a local enhancement of the reconnection rate or to the spacecraft crossing the electron diffusion region, Fig. 1b, where the electrons do not move with the E×B/B2 field-line velocity. We can estimate the dimensionless reconnection rate defined as R=Vin/VA, where VA is the Alfvén velocity on both sides of the current sheet. We find R≈0.1, implying that magnetic reconnection is fast, in agreement with numerical simulations19 and previous observations26. indicates that the two sides are magnetically connected, implying that the topology of the magnetic field has changed at the X-line. The normal magnetic field, Fig. 4c, is slightly varying but on average BN≈−1 nT.
During reconnection, electromagnetic energy is converted into kinetic and thermal energy of the plasma1. Thus, plasma acceleration away from the X-line and plasma heating also strongly substantiate ongoing reconnection. Figure 4i shows that within the current sheet and thus electromagnetic energy is converted into kinetic and thermal energy of the plasma, the average value . Electrons are accelerated away from the X-line at velocity VE×B,L that is up to about 2VA, see Fig. 4j. Such velocities are expected from numerical simulations19, which show that electrons and ions are respectively super-alfvenic and sub-alfvenic in the ion diffusion region, whereas away from it they move together at the Alfvén speed. Electron heating can be seen in Fig. 4m. The spectrogram of the differential energy flux, dEF, shows that the thermal energy of the electrons, which is approximately the energy corresponding to the maximum dEF, increases in the centre of the current sheet with respect to both sides.
The evidence of crossing the ion diffusion region is the observations of a bifurcated current sheet and of the Hall magnetic and electric fields, expected during symmetric reconnection7,8,19,23,24,25,26. The change in the reconnecting component, BL (Fig. 4a), occurs in two main steps, thus indicating that the current sheet is bifurcated, as also seen in the out-of-plane current, jM (Fig. 4h). The current shows two peaks at the edges of the current sheet consistent with the two peaks in the out-of-plane velocity of the electrons VE×B,M, see Fig. 4k. In the centre of the current sheet, jM is not consistent with −VE×B,M either because the jM is mainly parallel to B there and the electron parallel velocity cannot be measured or because the spacecraft is crossing the electron diffusion region. BM, Fig. 4b, has the typical Hall bipolar signature expected in the ion diffusion region. B, Fig. 4d, decreases in the centre of the current sheet down to very close to the magnetic null, 1.5 nT, consistent with the spacecraft being close to the X-line in symmetric reconnection. The normal Hall electric field, EN (Fig. 4g), points on both sides towards the centre of the current sheet. There is a slight asymmetry between the two sides of the current sheet, EN is stronger (up to 8 mV m−1) on the left side (in addition, the BM component is stronger there). The electric potential drop across EN on the left side of the current sheet (calculated between 16:51:95 and 16:52:15) is about ∼100 V. A proton accelerated through such a potential jump gets a velocity ∼150 km s−1≈VA, that is, the expected velocity for ions outflowing away from the X-line. The observations are consistent with a crossing of the diffusion region south of the X-line as shown in Fig. 1b, namely BN<0, the sign of the bipolar BM and VE×B,L<0.
The observations in Fig. 4 together with multi-spacecraft observations in Fig. 3 provide evidence that the Cluster spacecraft are crossing the ion diffusion region during ongoing magnetic reconnection. The strongest evidence that reconnection is ongoing comes from the measurements of tangential electric field, normal magnetic field, plasma flows and thermal energy of the electrons, which show the plasma inflow and outflow in the reconnection region, the magnetic connection between both sides of the current sheet and the plasma heating during reconnection. The evidence for crossing the ion diffusion region is the Hall magnetic and electric fields. These results, combined with the fact that the reconnecting current sheet is found in the turbulent terrestrial magnetosheath, show, for the first time, in situ evidence of magnetic reconnection in a turbulent plasma. We clearly show that reconnection acts as an electromagnetic energy conversion mechanism as , in particular we prove that electromagnetic energy is dissipated into heating of the turbulent plasma because the thermal energy of the electrons is increased. We also show that magnetic reconnection in turbulent plasma is fast. Our findings have important implications for laboratory and astrophysical plasmas, where magnetic reconnection and turbulence are ubiquitous and turbulent reconnection should be common.
Finally, we discuss the possible relevance of turbulent reconnection in generating high-energy ions and electrons, which is suggested by the observation of high-energy ions (>10 keV≈50 kBTi) in Fig. 2a. In situ observations27 indicate the absence of high-energy ions and electrons in the solar wind, where reconnection creates large-scale reconnection X-lines. However, high-energy electrons have been found in the terrestrial magnetotail28, where reconnection is often localized within many small-scale magnetic islands. This is also indicated by numerical simulations29,30. We speculate that in a turbulent plasma, magnetic reconnection does not develop large-scale X-lines such as those at the terrestrial magnetopause31 or in the solar wind5, but instead it is most likely localized. If the production of high-energy particles occurs during localized small-scale reconnection, then particle acceleration to high energies should be common during turbulent reconnection. This can have important implications for particle acceleration in astrophysical plasmas, for example, for cosmic-ray acceleration10. However, to quantitatively assess particle acceleration due to turbulent reconnection, particle detectors with higher sensitivity and time resolution than those onboard Cluster are needed, such as those planned onboard the future mission NASA/MMS.
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Acknowledgements
We thank S. C. Buchert and the FGM team for the magnetic-field data and H. Nilsson and the CIS team for the particle data. Fruitful discussion with T. Phan is acknowledged. A.R. research was supported by the Swedish National Space Board and partially by NASA Grant No. NNG05GL27G during his stay at the Space Sciences Laboratory, Berkeley. D.S. research was supported by NASA Grant No. NNG05GL27G. A.V. research was supported by the Swedish Research Council.
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Retinò, A., Sundkvist, D., Vaivads, A. et al. In situ evidence of magnetic reconnection in turbulent plasma. Nature Phys 3, 235–238 (2007). https://doi.org/10.1038/nphys574
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DOI: https://doi.org/10.1038/nphys574
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