Nasa’s pioneering craft has been travelling through the universe after it was launched in August 1977 from Cape Canaveral, 15 days before its twin Voyager 1. Since then it has been moving away from Earth, and almost exactly a year ago it passed out of the sun’s protective bubble and into interstellar space.
When it did, it became only the second man-made object to travel outside the limits of our sun’s influence and into the “interstellar medium”. Its sibling Voyager 1 did so six years earlier, because it is on a different trajectory and moving faster.
Scientists have now revealed what they learnt from that mission out into the furthest reaches of our cosmic neighbourhood.
In a series of papers published in the Nature Astronomy, researchers confirmed the spacecraft’s journey into the “space between the stars” by noting a “definitive jump” in the density of the plasma – made up of charged particles and gas – in interstellar space.
According to the scientists, this jump was detected by one of the instruments on Voyager 2 and is evidence of the probe making its way “from the hot, lower density plasma characteristic of the solar wind to the cool, higher-density plasma of interstellar space”.
It is also similar to the plasma density jump experienced by Voyager 1 when it crossed into interstellar space, the researchers added.
Among many things, the astronomers are looking to gain a better understanding of how the solar winds – the stream of charge particles coming out of the sun – interact with the interstellar winds – made up of particles from other stars.
Dr Edward Stone, a professor of physics at the California Institute of Technology and former director of Nasa’s Jet Propulsion Laboratory in Pasadena, California, said: “We are trying to understand the nature of the boundary where these two winds collide.”
The astronomers believe the probes’ journeys – with their different mission goals and trajectories – give “valuable clues” about the structure of the heliosphere – a vast bubble encompassing the sun and the solar system.
Bill Kurth, a research scientist at the University of Iowa and one of the authors of the studies, said: “It implies that the heliosphere is symmetric, at least at the two points where the Voyager spacecraft crossed.”
In one of the papers, the researchers suggest that the interstellar medium near the heliopause - the boundary where the sun’s solar winds are stopped by the interstellar medium – is hotter than expected, with a temperature of around 29,000-49,000C.
In another study, a different team reported the presence of layers “on both sides of the heliopause”.
While scientists were aware of the inner layer, the presence of the outer layer became evident only after Voyager 2 crossed into interstellar space.
The researchers said evidence gathered by both probes show that the interstellar medium, along with the heliopause and the interstellar magnetic fields, “form a complex interconnected dynamical system”.
The Voyagers were sent initially to study the outer planets including Jupiter, Saturn, Uranus and Neptune, but then just kept on going.
Even though they made it out of the sun’s bubble, astronomers maintain that the Voyagers are still technically in the solar system because it stretches to the outer edge of the Oort cloud – comprising water ice, ammonia and methane – which surrounds the sun.
Dr Stone said the crafts’ plutonium power sources will eventually stop supplying electricity, at which point their instruments and their transmitters will die.
He added: “In another five years or so we may not have enough scientific instruments to power it any longer.”
Dr Kurth believes that both Voyagers “will outlast Earth”, adding: “They’re in their own orbits around the galaxy for five billion years or longer. And the probability of them running into anything is almost zero.”
Additional reporting by agencies
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