Is the Sun going to enter a million-degree galactic cloud of interstellar gas?

A group of scientists are suggesting that the Ribbon of enhanced emissions of Energetic Neutral Atoms(ENA) discovered last year by the NASA Small Explorer satellite IBEX could be explained by a geometric effect coming up because of approach of the Sun to the boundary between the Local Cloud of interstellar gas and another cloud of a very hot gas called the Local Bubble.

If their hypothesis is correct, IBEX is catching matter from a hot neighboring interstellar cloud, which the Sun might enter in a hundred years.

The first full-sky maps of the emissions of Energetic Neutral Atoms obtained last year by IBEX  showed a new arc-like feature called the Ribbon, later declared by NASA as one of the most important findings made in 2009.

Shortly after the discovery six hypotheses were proposed to explain the Ribbon, all of them predicting its relation to processes going on within the heliosphere or in its neighborhood. In a recent Astrophysical Journal Letters paper, a team of scientists led by Prof. Stan Grzedzielski from the Space Research Centre of the Polish Academy of Sciences in Warsaw, Poland, offered another explanation. “We observe the Ribbon," says Grzedzielski, "because the Sun is approaching a boundary between our Local Cloud of interstellar gas and another cloud of a very hot and turbulent gas.”

The Energetic Neutral Atoms registered by IBEX detectors are born out of ions (protons) speeding from the very hot Local Bubble, a cavity in the interstellar medium (ISM) of the Orion Arm of the Milky Way, when they exchange charge with the relatively cool atoms “evaporating” from the Local Interstellar Cloud, a denser region in the Local Bubble about 30 light years across that our Sun is travelling through.

The newly created ENA have no electrical charge and therefore can dash freely in straight lines from their birth site, oblivious of the impeding magnetic fields. Some of them may reach Earth orbit and be detected by IBEX, the researchers say. “Had the Ribbon ENA been created at the boundaries of the heliosphere, their birth site would be relatively nearby, within just a couple of hundreds of astronomical units," explains Dr Andrzej Czechowski from SRC PAS, one of the co-authors of the paper. “According to our hypothesis, they are born much, much farther away.”

The team suggests that the Ribbon ENA are born by electrical charge exchange between the atoms which “evaporate” from the Local Interstellar Cloud into the nearby Local Bubble of a very hot and fully ionized gas. The Local Bubble is probably a remnant of a series of supernova explosions that occurred a few million years ago and thus is not only very hot (at least a million degrees Kelvin), but also turbulent. The protons in the Local Bubble nearby to the boundary with the Local Cloud snatch electrons from the neutral atoms and run away in all directions, some of them reaching IBEX.

Local Interstellar Cloud Local Bubble and energetic neutral atoms
The Sun traveling through the Galaxy happens to cross at the present time a blob of gas about ten light-years across, with a temperature of 6-7 thousand degrees kelvin. This so-called Local Interstellar Cloud is immersed in a much larger expanse of a million-degree hot gas, named the Local Bubble. The energetic neutral atoms (ENA) are generated by charge exchange at the interface between the two gaseous media. ENA can be observed provided the Sun is close enough to the interface. The apparent Ribbon of ENA discovered by the IBEX satellite can be explained by a geometric effect: one observes many more ENA by looking along a line-of-sight almost tangent to the interface than by looking in the perpendicular direction. (Source: SRC/Tentaris,ACh/Maciej Frolow)

“If our hypothesis is correct, then we are catching atoms that originate from an interstellar cloud that is different from ours, ” says Dr. Maciej Bzowski, Co-Investigator of the mission and head of the Polish IBEX team.

But since the creation of such ENA atoms is occurring throughout the entire boundary layer between the clouds, why do we see the Ribbon?

“It’s a purely geometrical effect, which we observe because the Sun is presently just in the right place, within a thousand of astronomical units from the cloud boundary," says Grzedzielski. “If the cloud-cloud boundary is flat, or better slightly extruded towards the Sun, then it appears the thinnest towards the center of the Ribbon and thicker at the sides, right where we see the edge of the Ribbon. If we were farther away from the boundary, we would see no Ribbon, because all the ENAs would be re-ionized and dispersed in the intervening gas of the Local Cloud.”

The model they developed suggests that the boundary between the Local Cloud and the Local Bubble might be not within a few light years from the Sun, as it was believed earlier, but within just a thousand astronomical units, a thousand-fold closer. This might mean that the Solar System could enter the million-degree Local Bubble cloud as early as the 22nd century.

“Nothing unusual, the Sun frequently traverses various clouds of interstellar gas during its galactic journey,” comments Grzedzielski. Such clouds are of very low density, much lower than the best vacuum obtained in the Earth labs. Once in, the heliosphere will reform and may shrink a little, the level of cosmic radiation entering the magnetosphere may rise a bit, but nothing more. “Perhaps future generations will have to learn how to better harden their space hardware against stronger radiation.”

IBEX is the latest in NASA's series of low-cost, rapidly developed Small Explorers space missions. Southwest Research Institute in San Antonio, TX, leads and developed the mission with a team of US and international partners. NASA's Goddard Space Flight Center in Greenbelt, Md., manages the Explorers Program for NASA's Science Mission Directorate in Washington DC.  

Citation: S. Grzedzielski, M. Bzowski, A. Czechowski, H. O. Funsten, D. J. McComas, and N. A. Schwadron, “A POSSIBLE GENERATION MECHANISM FOR THE IBEX RIBBON FROM OUTSIDE THE HELIOSPHERE”, Astrophysical Journal Letters, vol. 715 no 2, pp L84, 2010  doi:10.1088/2041-8205/715/2/L84