Researchers have used plasma flows in a laboratory to understand how beam-like jets may form in space.
Streaming jets of high-speed matter produce some of the most stunning objects seen in space. Astronomers have seen them shooting out of young stars just being formed, X-ray binary stars, and even the supermassive black holes at the centers of large galaxies.
Theoretical explanations for what causes those beam-like jets have been around for years, but a new experiment using extremely high-powered lasers offers experimental verification of one proposed mechanism for creating them.
“This research is an example of how laboratory experiments can be used to test mechanisms that may produce what we observe in space,” says Eric Blackman, professor of physics and astronomy at the University of Rochester and one of the coauthors.
Blackman explains that he and his collaborators wanted to recreate conditions in the lab that lead to jets in space becoming collimated—or beam-like—rather than diverging.
Theory and computational simulations had suggested the possibility that jets might be created by “shock focused inertial confinement.” Blackman adds that the experiment “confirms that this particular mechanism is viable, even though other effects are likely to also be taking place.”
In their results, the researchers show evidence of the “shocks” predicted by theory, and which give the mechanism its name. These shocks are surfaces in space where there is a sudden change in the density, speed, and direction of a flow. According to theory, which is consistent with the new experiment, they are what cause the beam-like nature of the jets to form.
In Physical Review Letters, the researchers explain how they used the laser laboratory facility, LULI, at the École Polytechnique in France, to recreate these space jets. Collaborators at the University of Chicago supplied a sophisticated computer code FLASH, which they developed and adapted to help analyze the results.
“We have focused a very energetic laser beam on a tiny iron target—a little thinner than a human hair,” explains Alessandra Ravasio, who led the experiment. “In this way we can create a supersonic plasma flow.”
With nothing to prevent the resulting iron plasma from spreading out, it would flow quasi-spherically from the target. In order to see the effects of a surrounding wind, the researchers generated another lighter, supersonic plasma from a plastic ring surrounding the central target.
“The novelty of this experiment is in the way we spatially distribute the laser energy, with a central dot generating the iron flow and a outer ring incident on the plastic,” adds Ravasio. “In this way we could create a nested geometry and study the interaction between the two flows.”
The researchers find that the interaction of the two plasmas sharply collimates the iron plasma flow. That is, rather than spreading out in all directions, the iron flow emanates primarily along a single direction. The experimental data shows that a shock wave is generated in this interaction, which helps the momentum and inertia of the plastic outer wind to collimate the inner iron flow into a jet.
The experiment is an example of laboratory astrophysics, a rapidly growing area of high energy density physics that requires the collaboration of astrophysicists, experimental plasma physicists, and computational physicists.
The team of collaborators includes additional researchers from École Polytechnique, France; the Joint Institute for High Temperature RAS in Moscow, Russia; CEA-DAM-DIF, France; and the University of Chicago.
Source: University of Rochester