HSTOF ENA observations and energetic ion distributions in the heliosheath

Czechowski, A.; Hilchenbach, M.; Hsieh, K. C.

doi:10.1051/0004-6361/201118570

Cited by 7 publications

(28 citation statements)

References 45 publications

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“…This implies that the thickness of the heliosheath beyond the S/C location in August 2012 is very small if not null. Such a conclusion is in line with other results based on Voyager 1 data suggestive of an entrance in the ISM: (i) the heliosheath energetic particle disappearance (Krimigis et al 2013); (ii) the abrupt increases in the GCRs and the new spectra (Stone et al 2013;Webber & McDonald 2013;Webber et al 2013a); (iii) the solar wind stagnation since 2010 Krimigis et al 2011); (iv) the comparisons between the Cassini, SOHO/HSTOF and IBEX data, on one hand, and Voyager particle data, on the other hand, which provided estimates of the heliosheath thickness in the Voyager 1 direction (21 ± 6, Hsieh et al 2010;Czechowski et al 2012 and 31(+31, −18) AU Roelof et al 2012); (v) the constancy of the IPGH proton flux (plus UVS, if corrected for anisotropies) for more than a year now, which has never happened since at least 1992; and (vi) the recent measurements of plasma oscillations that imply a high density at V1 ).…”

Section: Conclusion and Discussionmentioning

confidence: 99%

Galactic cosmic rays measured by UVS on Voyager 1 and the end of the modulation

Lallement

Bertaux

Quémerais

et al. 2014

A&A

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The detectors of the Ultraviolet Spectrographs (UVS) on Voyager 1/2 are recording a background intensity that was earlier assigned mainly to disintegrations in the radio-isotope thermoelectric generator and systematically subtracted from the signal to infer photon counting. Here, we show that it arises instead from galactic cosmic rays (GCRs). We show the GCR flux measured by UVS on Voyager 1 from 1992 to August 2013, and by comparing to data from the GCR dedicated detectors, we estimate the energy range responsible for this UVS signal, which is around 300 MeV, and the response of UVS to the GCR anisotropy. After the abrupt jumps of May and August 2012, the count rate has been only slightly fluctuating around a constant value. However, comparing it to the data from the Low Energy Charge Particle Experiment (LECP) and the Cosmic Ray Subsystem (CRS) shows that those small variations are only responses to a varying anisotropy and not to a flux change. Taking advantage of the similarity in energy range to one of the products of the CRS instrument suite, we use the ratio between the two independent signals as a proxy for the temporal evolution of the GCR spectral slope around the 300 MeV range. We show that this slope remained unchanged since August 2012 and find strong evidence that it will no longer vary, implying the end of the heliospheric modulation at those energies, and that Voyager 1 at this date is near or past the heliopause. The origin of this unexpectedly narrow and stagnating inner heliosheath is still unclear, and we discuss the potential effects of low solar wind speed episodes and subsequent self-amplified charge-exchange with interstellar neutrals, as a source of deceleration and collapse. We suggest that the quasi-static region encountered by Voyager 1 may be related to such effects, triggered by the strong solar-maximum variability. This did not happen for Voyager 2 due to its trajectory at an angle further from the heliosphere axis and a later termination shock crossing. The existence on the upwind side of a mixing layer formed by charge transfer instead of a pure plasma contact discontinuity could explain various Voyager 1 observations.

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Section: Conclusion and Discussionmentioning

confidence: 99%

Galactic cosmic rays measured by UVS on Voyager 1 and the end of the modulation

Lallement

Bertaux

Quémerais

et al. 2014

A&A

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“…The first ENA observation of the heliosheath were performed with the HSTOF sensor of the CELIAS instrument on the SOHO mission for hydrogen ENAs in the energy range from 55-80 keV [54]. In [55], the final analysis of these data is presented for hydrogen and helium ENAs originating in the heliosheath. At lower energies, in the range from 400 eV to 5 keV, the first hydrogen observations were done by the ASPERA-3 and ASPERA-4 ENA instruments on the Mars Express and Venus Express spacecraft [56].…”

Section: What Is the Correlation Between The Ibex Soho And Voyager mentioning

confidence: 99%

“…By considering the charge exchange cross-sections, the energy spectra of protons in the heliosheath were derived, extending the range covered by the instrumentation of the Voyager spacecraft. Before IBEX measurements, the covered energy range spanned from 400 eV to 80 keV [56,58,55,59], including the HENA data from the IMAGE mission, with the most recent compilation of the ENA energy spectra given in [57]. From the fit of the proton spectra, which were derived from these ENA energy spectra, to the in situ proton spectra from Voyager at higher energies, which is the only fit parameter, the thickness of the heliosheath in the upwind direction can be estimated to be between 35-70 AU.…”

Section: What Is the Correlation Between The Ibex Soho And Voyager mentioning

confidence: 99%

Heliosheath Processes and the Structure of the Heliopause: Modeling Energetic Particles, Cosmic Rays, and Magnetic Fields

et al. 2017

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Publication resulting from an International ISSI Team of the same name. Submitted to Space Science ReviewsInternational audienceThis paper summarizes the results obtained by the team "Heliosheath Processes and the Structure of the Heliopause: Modeling Energetic Particles, Cosmic Rays, and Magnetic Fields" supported by the International Space Science Institute in Bern, Switzerland. We focus on the physical processes occurring in the outer heliosphere, especially at its boundary called the heliopause (HP), and in the LISM. The importance of magnetic field, charge exchange between atoms and ions, and solar cycle on the heliopause topology and observed heliocentric distances to different heliospheric discontinuities are discussed. It is shown that time-dependent boundary conditions are necessary to describe the heliospheric asymmetries detected by the Voyager spacecraft. We also discuss the structure of the HP, especially due to its instability and magnetic reconnection. It is demonstrated that the Rayleigh-Taylor instability of the nose of the HP creates consecutive layers of the interstellar and heliospheric plasma which are magnetically connected to different sources. This may be a possible explanation of abrupt changes in the galactic and anomalous cosmic ray fluxes observed by Voyager 1 when it was crossing the HP structure for a period of about one month in the summer of 2012. This paper also discusses the plausibility of fitting simulation results to a number of observational data sets obtained by in situ and remote measurements. The distribution of magnetic field in the vicinity of the HP is discussed in the context of Voyager measurements. We discuss the transport of energetic particles in the inner and outer heliosheath, concentrating on the anisotropic spatial diffusion diffusion tensor and the pitch-angle dependence of perpendicular diffusion and demonstrate that the latter can explain the observed pitch-angle anisotropies of both the anomalous and galactic cosmic rays in the outer heliosheath

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“…The last term, L esc,He + = f He + /τ esc , describes diffusive escape through the heliopause with escape time τ esc . It was added following Czechowski et al (2012). Time τ esc corresponds to a random walk over the shortest distance l HP separating the considered point from the heliopause.…”

Section: Physical Model Of Processes Leading To Emergence Of Tens-of-mentioning

confidence: 99%

Solar wind He pickup ions as source of tens-of-keV/n neutral He atoms observed by the HSTOF/SOHO detector

Grzędzielski

Swaczyna

Czechowski

et al. 2014

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Context. Since 1996, during periods of low solar activity, the HSTOF instrument on board the SOHO satellite has been measuring weak fluxes of He atoms of 28-58 keV/n (helium energetic neutral atoms, He ENAs). The probable source region is the inner heliosheath. Aims. We aim to understand the emission mechanism of He ENAs based on knowledge of the heliosheath spatial extent and plasma content resulting from Voyager 1 and 2 measurements in the period after termination shock crossings. Methods. He ENAs are generated by charge-exchange neutralization of energetic helium ions on interstellar neutral H and He. Energy spectra of helium ions in the heliosheath are calculated by following the evolution of their velocity distribution functions when carried by and undergoing binary interactions with plasma constituents of a background flow whose particle populations are modeled to approximately render post-termination-shock Voyager data. Results. The observed HSTOF He ENAs form a higher energy part of general heliospheric He ENA fluxes and can be explained by the proposed mechanism to within 2σ error. The main factor determining the level of emission (and its uncertainty) is the energy spectrum of He + pickup ions in post-termination-shock plasmas.

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HSTOF ENA observations and energetic ion distributions in the heliosheath

Cited by 7 publications

References 45 publications

Galactic cosmic rays measured by UVS on Voyager 1 and the end of the modulation

Galactic cosmic rays measured by UVS on Voyager 1 and the end of the modulation

Heliosheath Processes and the Structure of the Heliopause: Modeling Energetic Particles, Cosmic Rays, and Magnetic Fields

Solar wind He pickup ions as source of tens-of-keV/n neutral He atoms observed by the HSTOF/SOHO detector

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