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Voyager facts

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Voyager mission

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the solar wind

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High-resolution images:

Image 1

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Image 2

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Image 2a

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Labeled Image 2a

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Black and White Image 2a

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Caption for Animation 1 and Images 1 & 2:

This is an artist's concept illustrating the structures the solar wind forms around our Sun. As we fly out from the Sun beyond the orbits of the planets, we come to the termination shock (semi-transparent purple sphere in Image 1). The termination shock is where the solar wind, a thin stream of electrically charged gas blown constantly from the Sun, is slowed abruptly by pressure from gas between the stars. Beyond this region is the solar system's final frontier - the heliosheath. The heliosheath is a vast region where the solar wind is turbulent and hot (dark purple area in Image 2). As the camera moves outward, we see the heliosheath on the largest scales. The interstellar wind collides with the heliosheath and forms a structure called the bow shock (red and orange areas in Image 2), forcing the heliosheath into a long, teardrop shaped structure. Image 2a shows the positions of the Voyager spacecraft in relation to these structures.

Credit: NASA/Walt Feimer

Image 3

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Image 4

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Image 5

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Image 6

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Caption for Animation 2 and Images 3 - 6:

This is an artist's concept illustrating where our solar system's final frontier, the heliosheath, fits in relation to our galaxy. The camera begins the journey far outside our home galaxy, the Milky Way (Image 3). As we move in closer, we come to the spiral arm where our Sun resides (Image 4). As we approach the Sun deep in the arm, we see the stars that inhabit our local celestial neighborhood (Image 5). Finally, we are close enough to resolve the heliosheath and bow shock around our Sun. The bow shock is represented by the yellow-orange, crescent-shaped structure in Image 6, and the heliosheath is the faint blue teardrop shaped area in the same image.

Credit: NASA/Walt Feimer

Image 7

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Caption for Image 7:

NASA's Hubble Space Telescope continues to reveal various stunning and intricate treasures that reside within the nearby, intense star-forming region known as the Great Nebula in Orion. One such jewel is the bow shock around the very young star, 1998 WW31, featured in this Hubble Heritage image.

Named for the crescent-shaped wave made by a ship as it moves through water, a bow shock can be created in space when two streams of gas collide. LL Ori emits a vigorous solar wind, a stream of charged particles moving rapidly outward from the star. Our own Sun has a less energetic version of this wind that is responsible for auroral displays on the Earth.

The material in the fast wind from LL Ori collides with slow-moving gas evaporating away from the center of the Orion Nebula, which is located to the lower right in this Heritage image. The surface where the two winds collide is the crescent-shaped bow shock seen in the image.

Unlike a water wave made by a ship, this interstellar bow shock is a three-dimensional structure. The filamentary emission has a very distinct boundary on the side facing away from LL Ori, but is diffuse on the side closest to the star, a characteristic common to many bow shocks.

A second, fainter bow shock can be seen around a star near the upper right-hand corner of the Heritage image. Astronomers have identified numerous shock fronts in this complex star-forming region and are using this data to understand the many complex phenomena associated with the birth of stars.

This image was taken in February 1995 as part of the Hubble Orion Nebula mosaic. A close visitor in our Milky Way galaxy, the nebula is only 1,500 light-years from Earth. The filters used in this color composite represent oxygen, nitrogen, and hydrogen emissions.

Image Credit: NASA and The Hubble Heritage Team (STScI/AURA)
Acknowledgment: C. R. O'Dell (Vanderbilt University)

Movie 3 caption:

This movie shows water flowing over a plate as an analogy for the termination shock. Estimating the location of the termination shock is hard because we don't know the precise conditions in interstellar space, and even what we do know, the speed and pressure of the solar wind, changes which causes the termination shock to expand, contract, and ripple. You can see a similar effect every time you wash dishes. If you place a plate underneath a stream of water, you notice the water spreads out over the plate in a relatively smooth flow. The water flow has a rough edge where the water slows down abruptly and piles up. The edge is like the termination shock, and as the water flow changes, the shape and size of the rough edge change.

Credit: NASA/European Space Agency

Movie 4 caption:

This is a computer model of the structures formed by the solar wind as it blows against the interstellar wind. Colors represent temperature of the solar and interstellar plasmas; blue is coolest, and red is hottest. The area closest to the Sun is the blue dot in the center of the green circular area. As the solar wind slows and becomes turbulent in the heliosheath, its temperature increases (red, teardrop-shaped area). Cooler interstellar plasma surrounds the heliosheath (large blue area). If you play the movie several times in rapid succession, you can see how changes in solar wind pressure create changes in the heliosheath.

Credit: Hans Mueller (Dartmouth College), Gary Zank (University of California at Riverside), and NASA

The Top Story Archive listing can be found by clicking on this link.

All stories found on a Top Story page or the front page of this site have been archived from most to least current on this page.

For a list of recent press releases, click here.

November 5, 2003 - (date of web publication)

	Animation 1
	Click here for 19 meg quick time movie Click here for 8 meg mpeg movie

NASA's Voyager 1 spacecraft is about to make history again as the first spacecraft to enter the solar system's final frontier, a vast expanse where wind from the Sun blows hot against thin gas between the stars: interstellar space. However, before it reaches this region, Voyager 1 must pass through the termination shock, a violent zone that is the source of beams of high-energy particles (Image 1).

	Animation 2
	Click here for 8 meg quick time movie Click here for 5 meg mpeg movie

Voyager's journey through this turbulent zone will give scientists their first direct measurements of our solar system's unexplored final frontier, called the heliosheath, and scientists are debating if this passage has already begun. Two papers about this research are being published in Nature on November 5, 2003. The first paper, by Dr. Stamatios M. Krimigis of the Johns Hopkins University Applied Physics Laboratory, Laurel, Md., and his team, gives evidence supporting the claim that Voyager 1 passed beyond the termination shock. The second paper, by Dr. Frank B. McDonald of the University of Maryland, College Park, and his team, gives evidence against this claim. A third paper, published October 30, 2003 in Geophysical Research Letters by Dr. Leonard F. Burlaga of NASA's Goddard Space Flight Center, Greenbelt, Md., and collaborators, gives evidence that Voyager 1 did not pass beyond the termination shock. (Refer to Image 2a for an illustration of the termination shock and heliosheath).

	Movie 3
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"The Voyager 1 observations show we have entered into a new part of the solar system. Regardless of whether we crossed the termination shock or not, the teams are excited because this has never been seen before - the observations are different here than in the inner solar system," said Dr. Eric Christian, Discipline Scientist for the Sun Earth Connection research program at NASA Headquarters, Washington, DC.

	Movie 4
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"Voyager 1 has seen striking signs of the region deep in space where a giant shock wave forms as the wind from the Sun abruptly slows and presses outward against the interstellar wind. The observations surprised and puzzled us, so there is much to be discovered as Voyager begins exploring this new region at the outer edge of the solar system," said Dr. Edward Stone, Voyager Project Scientist, California Institute of Technology, Pasadena, Calif.

	Image 1

At more than eight billion miles (13 billion km) from the Sun, Voyager 1 is the most distant object built by humanity. Launched on September 5, 1977, it explored the giant planets Jupiter and Saturn before being tossed out toward deep space by Saturn's gravity. It now approaches, and may have temporarily entered, the region beyond termination shock. (Refer to image 2a for a schematic illustrating the current locations of the Voyager spacecraft.)

	Image 2

The termination shock is where the solar wind, a thin stream of electrically charged gas blown constantly from the Sun, is slowed by pressure from gas between the stars. At the termination shock, the solar wind slows abruptly from its average speed of 300 - 700 km per second (700,000 - 1,500,000 mph). (Refer to Movie 4 to see how this heats the solar wind in the heliosheath).

	Image 2a

The exact location of the termination shock is unknown, and it originally was thought to be closer to the Sun than Voyager 1 currently is. As Voyager 1 cruised ever farther from the Sun, it confirmed that all the planets were inside an immense bubble blown by the solar wind, and the termination shock was much more distant (Animation 1).

	Image 3

Estimating the location of the termination shock is hard because we don't know the precise conditions in interstellar space, and even what we do know, the speed and pressure of the solar wind, changes which causes the termination shock to expand, contract, and ripple. You can see a similar effect every time you wash dishes (Movie 3). If you place a plate underneath a stream of water, you notice the water spreads out over the plate in a relatively smooth flow. The water flow has a rough edge where the water slows down abruptly and piles up. The edge is like the termination shock, and as the water flow changes, the shape and size of the rough edge change.

	Image 4

From about August 1, 2002 to February 5, 2003, scientists noticed unusual readings from the two energetic particle instruments on Voyager 1, indicating it had entered a region of the solar system unlike any encountered before. This led some to claim that Voyager may have entered a transitory feature of the termination shock. Just as small bumps and "fingers" appear and disappear in the rough edge of the water flow over a plate, Voyager might have entered a temporary "finger" in the edge of the termination shock.

	Image 5

The controversy would be resolved easily if Voyager could still measure the speed of the solar wind, because the solar wind slows abruptly at the termination shock. However, the instrument that measures solar wind speed no longer functions on the venerable spacecraft, so scientists must use data from the instruments that are still working to infer if Voyager pierced the termination shock.

	Image 6

Evidence for crossing the shock includes Voyager's observation that high-velocity electrically-charged particles (electrons and ions) increased more than 100 times during the August 1, 2002 to February 5, 2003 period. This would be expected if Voyager passed the termination shock, because the shock naturally accelerates electrically charged particles that bounce back and forth like ping pong balls between the fast and slow winds on the opposite sides of the shock.

	Image 7

Secondly, the particles were flowing outward, past Voyager and away from the Sun. This would be expected if Voyager already crossed beyond the termination shock, because the acceleration region in the termination shock would now be behind the spacecraft. Third, an indirect measure of the solar wind speed indicated the solar wind was slow during this period, as would be expected if Voyager was beyond the shock.

"We have used an indirect technique to show that the solar wind slowed down from about 700,000 mph to much less than 100,000 mph. This same technique was used by us before, when the instrument measuring the solar wind speed was still working, and the agreement between the two measurements was better than 20% in most cases," said Krimigis.

Evidence against entry into the shock includes the observation that while there was a dramatic increase in low-speed particles, they weren't seen at the somewhat higher speeds scientists believe the termination shock generates.

However, the strongest evidence against entry is Voyager's observation that the magnetic field did not increase during this period. According to theoretical models, this must happen whenever the solar wind slows down. Imagine a highway with moderate traffic. If something makes the drivers slow down, say a puddle of water, the cars pile up - their density increases. In the same way, the density (intensity) of the magnetic field carried by the solar wind will increase if the solar wind slows down.

"The analysis of the Voyager 1 magnetic field observations in late 2002 indicate that it did not enter a new region of the distant heliosphere by having crossed the termination shock. Rather, the magnetic field data had the characteristics to be expected based upon many years of previous observations, although the intensity of energetic particles observed is unusually high," said Burlaga.

The teams agree that Voyager 1 has seen a new phenomenon: a six-month period when low-energy particles were very abundant and flowing away from the Sun. When the unusual period ended, both agree that Voyager 1 was back in the solar wind, so if this was a temporary passage beyond the termination shock, the shock will be seen again, probably in the next couple years. Finally, the observations indicate that the termination shock is a lot more complicated than anyone thought.

For their original missions to Jupiter and Saturn, Voyager 1 and sister spacecraft Voyager 2 were destined to regions of space where solar panels would not be feasible, so each was equipped with three radioisotope thermoelectric generators to produce electrical power for the spacecraft systems and instruments. Still operating in remote, cold and dark conditions 26 years later, the Voyagers owe their longevity to these Department of Energy-provided generators, which produce electricity from the heat generated by the natural decay of plutonium dioxide.

The Voyagers were built by NASA's Jet Propulsion Laboratory (JPL) in Pasadena, Calif., which continues to operate both spacecraft 26 years after their launch. The spacecraft are controlled and their data returned through NASA's Deep Space Network (DSN), a global spacecraft tracking system also operated by JPL. The Voyager Project Manager is Ed Massey of JPL. The Voyager Project Scientist is Dr. Edward Stone of the California Institute of Technology.

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