New Study Predicts Slow Bow Shock Ahead of the Sun’s Heliosphere

Voyager data could confirm presence of solar bow shock

Article ID: 605540

Released: 18-Jul-2013 10:35 AM EDT

Source Newsroom: Boston University College of Arts and Sciences

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  • Credit: NASA/Hubble Heritage Team

    NASA's Hubble Space Telescope (HST) captured this image of what appears to be a fast bow shock around a very young star in the Great Nebula in Orion. New research predicts a comparable slow bow shock ahead of the sun’s heliosphere.

Newswise — A new study co-authored by Boston University astronomers indicates that a bow shock (a dynamic boundary between sun’s heliosphere and the interstellar medium) is highly likely. These findings challenge recent predictions that no such bow shock would be encountered.

The researchers base their expectation of finding a bow shock on a new magneto-hydrodynamic simulation that confirmed a theoretically expected slow bow shock (SBS) ahead of the heliosphere. The new research supports the idea that the sun, like a boat moving through water, forms a crescent-shaped shockwave as it moves through interstellar gas. The study, titled “A slow bow shock ahead of the heliosphere,” was published recently in the journal Geophysical Research Letters (Geophysical Research Letters, Vol. 40, 1–6, doi: 10.1002/grl.50576, 2013).

In the current study, Bertalan Zieger, lead author and research scientist at BU’s Center for Space Physics, and colleagues predict that a slow bow shock should exist ahead of the heliosphere. This challenges some recent models that argued no bow shock at all would be found. Those studies, which used the Interstellar Boundary Explorer (IBEX) satellite to measure the speed of interstellar particles entering the solar system near the edge of the heliosphere, suggested that the sun was moving too slowly through interstellar space (at 52,000 miles an hour) to create a bow shock.

However, the bow shock that they refer to is what is called a fast bow shock. The new study shows that a slow type is possible: IBEX observations also indicate that the interstellar wind is slower than the fast and the intermediate wave, but faster than the slow wave. Using these observations, the researchers conducted a magneto-hydrodynamic simulation that predicts a slow bow shock should exist in front of the heliosphere.

These projections could soon be confirmed by actual data: Voyager 1 is heading toward the slow bow shock, while Voyager 2 is not, which means that the two spacecraft are expected to encounter different interstellar plasma populations beyond the heliopause. Confirmation of the existence of a bow shock could have important implications for our understanding of the nature of the interstellar magnetic field that the Voyagers will encounter ahead of the heliopshere, including whether the slow bow shock filters the influx of high-energy cosmic rays into the heliosphere.

The following authors contributed to this study: B. Zieger and M. Opher, Center for Space Physics, Boston University; N. A. Schwadron, Center for Space Physics, Boston University, Institute for the Study of Earth, Oceans and Space, University of New Hampshire, and Southwest Research Institute, San Antonio, Texas; D. J. McComas, Southwest Research Institute, San Antonio, Texas; Physics and Astronomy Department, University of Texas, San Antonio; G. Tóth, Department of Atmospheric, Oceanic, and Space Sciences, University of Michigan.

About Boston University—Founded in 1839, Boston University is an internationally recognized private research university with more than 30,000 students participating in undergraduate, graduate, and professional programs. As Boston University’s largest academic division, the College and Graduate School of Arts & Sciences is the heart of the BU experience with a global reach that enhances the University’s reputation for teaching and research. In 2012, BU joined the Association of American Universities (AAU), a consortium of 62 leading research universities in the United States and Canada.

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Corresponding author for the study:

Dr. Bertalan ZiegerBoston UniversityCenter for Space Physics725 Commonwealth AvenueBoston, MA 02215,



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