University of Iowa space physicist Don Gurnett says there is solid evidence that NASA’s Voyager 1 spacecraft has become the first manmade object to reach interstellar space, more than 11 billion miles distant and 36 years after it was launched.
The finding is reported in a paper published in the Sept. 12 online issue of the journal Science.
“On April 9, the Voyager 1 Plasma Wave instrument, built at the UI in the mid-1970s, began detecting locally generated waves, called electron plasma oscillations, at a frequency that corresponds to an electron density about 40 times greater than the density inside the heliosphere—the region of the sun’s influence,” says Gurnett. “The increased electron density is very close to the value scientists expected to find in the interstellar medium.
“This is the first solid evidence that Voyager 1 has crossed the heliopause, the boundary between the heliosphere, and interstellar space,” says Gurnett, principal investigator for the plasma wave instrument.
For several months, the relative position of Voyager 1 has stirred something of a scientific debate because there remains some lingering evidence of the nearby heliosphere beyond the heliopause.
A short history of Voyager's historic journey
When NASA’s Voyager 1 spacecraft became the first manmade object to enter interstellar space, it claimed an iconic place in in the history of space exploration—and underscored the University of Iowa's role and legacy among the stars. Story/video
Even though Voyager 1 has passed into interstellar space, it does not mean that its journey is over, says Bill Kurth, UI research scientist and co-author of the Science paper.
“Now that we’re on the outside, we are learning that interstellar space isn’t a bland region,” Kurth says. “Rather, there are variations in some of Voyager’s measurements that may be due to the nearby presence of the heliosphere. So, our attention is turning from crossing the boundary to understanding what is going on outside,” he says.
At age 36, Voyager 1 is the most distant human-made object at more than 11.6 billion miles from the sun, or about 125 astronomical units.
“At that distance it takes more than 17 hours for a radio signal to travel from the spacecraft to one of NASA’s Deep Space Network antennas. The signal strength is so incredibly weak that it takes both a 230-foot and a 110-foot-diameter antenna to receive our highest resolution data,” Gurnett says.
Launched Sept. 5, 1977, Voyager 1 completed flybys of both Jupiter and Saturn and is currently moving outward from the sun at about 3.5 AU per year. A sister spacecraft, Voyager 2 was launched Aug. 20, 1977, on a flight path that took it to encounters with Jupiter, Saturn, Uranus, and Neptune. At present, Voyager 2 is still inside the heliosphere about 103 AU from the sun and traveling outward at about 3.3 AU per year.
The sounds of the electron plasma oscillations heralding Voyager’s entry into interstellar space and other sounds of space can be heard by visiting Gurnett’s website.
Gunett’s and Kurth’s co-authors on the Science paper are L.F. Burlaga of NASA/Goddard Space Flight Center, Greenbelt, Md.; and N.F. Ness of The Catholic University of America, Washington, D.C. For more information on the Science paper, visit here.
NASA’s Jet Propulsion Laboratory (JPL), Pasadena, Calif., a division of Caltech, manages the Voyager mission for NASA's Science Mission Directorate, Washington, D.C. For more information on Voyager, visit the NASA website.
Hear, hear: Gurnett and Kurth will give a public lecture on this topic Sept. 16.