Observations of the magnetic field and plasma in the heliosheath by Voyager 2 from 2007.7 to 2009.4

Burlaga, L. F.; Ness, N. F.; Wang, Y.-M.; Sheeley, N. R.; Richardson, J. D.

doi:10.1029/2009ja015239

Cited by 25 publications

(19 citation statements)

References 28 publications

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“…The V2 magnetic field observations from 2007.0 through 2012 have been discussed in previous papers (Burlaga et al 2009(Burlaga et al , 2010Richardson & Burlaga 2013). Figure 1 also includes the new observations for the years 2013 and 2014, which are the main subject of the present paper.…”

Section: Overviewmentioning

confidence: 87%

“…Nevertheless, Figure 1 shows that there is a broad interval, with no sharp boundaries (for the reasons given above) in which the magnetic field is directed primarily away from the Sun (the unipolar region) from ∼2009.6 to ∼2013.8245. Earlier, Burlaga et al (2009Burlaga et al ( , 2010, based on alimited data set, estimated that V2 was in this unipolar region from ∼2009.5 to at least 2010.3.…”

Section: Transition From the Sector Zone To The Unipolar Region Durinmentioning

confidence: 98%

“…Burlaga et al (2009Burlaga et al ( , 2010 showed that the transition from the sector zone to the unipolar region was caused by the decreasing latitudinal extent of the sector zone. This motion was inferred by Burlaga et al (2009) from variations of the neutral line on the source surface, using the solar magnetic field data from the Wilcox Solar Observatory and the Mount Wilson Observatory data.…”

Section: Transition From the Sector Zone To The Unipolar Region Durinmentioning

confidence: 99%

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Transition from the Unipolar Region to the Sector Zone: Voyager 2, 2013 and 2014

Burlaga

Ness

Richardson

2017

ApJ

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We discuss magnetic field and plasma observations of the heliosheath made by Voyager 2 (V2) during 2013 and 2014 near solar maximum. A transition from a unipolar region to a sector zone was observed in the azimuthal angle λ between ∼2012.45 and 2013.82. The distribution of λ was strongly singly peaked at 270 in the unipolar region and double peaked in the sector zone. The δ-distribution was strongly peaked in the unipolar region and very broad in the sector zone. The distribution of daily averages of the magnetic field strength B was Gaussian in the unipolar region and lognormal in the sector zone. The correlation function of B was exponential with an e-folding time of ∼5 days in both regions. The distribution of hourly increments of B was a Tsallis distribution with nonextensivity parameter q=1.7±0.04 in the unipolar region and q=1.44±0.12 in the sector zone. The CR-B relationship qualitatively describes the 2013 observations, but not the 2014 observations. A 40 km s −1 increase in the bulk speed associated with an increase in B near 2013.5 might have been produced by the merging of streams. A "D sheet" (a broad depression in B containing a current sheet moved past V2 from days 320 to 345, 2013. The Rand N-components of the plasma velocity changed across the current sheet.

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Section: Overviewmentioning

confidence: 87%

Section: Transition From the Sector Zone To The Unipolar Region Durinmentioning

confidence: 98%

Section: Transition From the Sector Zone To The Unipolar Region Durinmentioning

confidence: 99%

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Transition from the Unipolar Region to the Sector Zone: Voyager 2, 2013 and 2014

Burlaga

Ness

Richardson

2017

ApJ

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“…For example, the presence of compressive structures in slow solar wind could be the result of the in- teraction of the wind with the heliospheric current sheet (Burlaga et al 2002;Brooks et al 2015) or be remnant features of large scale coronal structures (Wilcox & Ness 1967;McComas et al 2000). Thanks to Solar Orbiter and Parker Solar Probe, it will be possible to measure the turbulent and structured electric and magnetic fields associated with shocks, reconnection and stochastic energization in unexplored plasma environments, investigating plasma physics in the source regions of both fast and slow wind.…”

Section: Conclusion and Discussionmentioning

confidence: 99%

Coherent Structures at Ion Scales in Fast Solar Wind: Cluster Observations

Perrone

Alexandrova

Roberts

et al. 2017

ApJ

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We investigate the nature of magnetic turbulent fluctuations, around ion characteristic scales, in a fast solar wind stream, by using Cluster data. Contrarily to slow solar wind, where both Alfvénic (δb ⊥ ≫ δb ) and compressive (δb ≫ δb ⊥ ) coherent structures are observed (Perrone et al. 2016), the turbulent cascade of fast solar wind is dominated by Alfvénic structures, namely Alfvén vortices, with small and/or finite compressive part, with the presence also of several current sheets aligned with the local magnetic field. Several examples of vortex chains are also recognized. Although an increase of magnetic compressibility around ion scales is observed also for fast solar wind, no strongly compressive structures are found, meaning that the nature of the slow and fast winds is intrinsically different. Multi-spacecraft analysis applied to this interval of fast wind indicate that the coherent structures are almost convected by the flow and aligned with the local magnetic field, i.e. their normal is perpendicular to B, that is consistent with a two dimensional turbulence picture. Understanding intermittency and the related generation of coherent structures could provide a key insight into the nonlinear energy transfer and dissipation processes in magnetized and collisionless plasmas.

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“…Burlaga et al 2002;Murphy et al 2002;Mursula 2007;Roberts et al 2007;Mordvinov 2008;Ebert et al 2009) and corresponding modeling (e.g. Burger & Hitge 2004;Giacalone & Jokipii 2004;Burger 2005;Schwadron & McComas 2005;Giacalone et al 2006;Ferreira et al 2007;Burger et al 2008) that can be used to analyze the asymmetry of the HMF have not yet convincingly settled the debate over which of the fields is closest to reality.…”

Section: Introductionmentioning

confidence: 99%

Comparison of different analytic heliospheric magnetic field configurations and their significance for the particle injection at the termination shock

Scherer¹,

Fichtner²,

Effenberger³

et al. 2010

A&A

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Context. Heliospheric magnetic field configurations are relevant on a large scale for the transport of cosmic rays, especially for injecting possibly pre-accelerated particles into the Fermi-I acceleration process of cosmic rays. Aims. We compare four analytically described fields by calculating the scalar product between their vectors and the corresponding vectors of the Parker spiral field. Because the injection efficiency at the termination shock is highly sensitive to the local inclination of the upstream magnetic fields with respect to the shock normal, we discuss the probability that pick-up ions are injected into the Fermi-I process. Methods. We extend the previous work comparing different analytically described heliospheric magnetic fields: the Parker and hybrid Fisk field and modifications of both. Because the Fisk-like configurations are only present during periods of low to moderate solar activity, we restrict ourselves to this case by including high-speed streams over the ecliptic and low-speed flow in the latter. In addition, we extend the analysis from an analytic approximation to a numerically computed termination shock surface. Results. We find that no strong differences in the injection efficiency can be expected for the four field configurations despite significant structural differences inside the termination. Conclusions. Consequently, the injection efficiency is largely insensitive to the large-scale heliospheric magnetic field configuration.

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Observations of the magnetic field and plasma in the heliosheath by Voyager 2 from 2007.7 to 2009.4

Cited by 25 publications

References 28 publications

Transition from the Unipolar Region to the Sector Zone: Voyager 2, 2013 and 2014

Transition from the Unipolar Region to the Sector Zone: Voyager 2, 2013 and 2014

Coherent Structures at Ion Scales in Fast Solar Wind: Cluster Observations

Comparison of different analytic heliospheric magnetic field configurations and their significance for the particle injection at the termination shock

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