ALMA sizes up grains of cosmic dust around failed star
The discovery of millimeter-sized dust grains around a brown dwarf suggests that this disk is more similar to the ones around young stars than previously thought.
December 3, 2012
Astronomers using the Atacama Large Millimeter/submillimeter Array (ALMA) have for the first time found that the outer region of a dusty disk encircling a brown dwarf contains millimeter-sized solid grains like those found in denser disks around newborn stars. The surprising finding challenges theories of how rocky, Earth-sized planets form and suggests that rocky planets may be even more common in the universe than expected.
This artist’s impression shows the disk of gas and cosmic dust around a brown dwarf. // Credit: ALMA (ESO/NAOJ/NRAO)/M. Kornmesser (ESO)
Rocky planets are thought to form through the random collision and sticking together of what are initially microscopic particles in the disk of material around a star. These tiny grains, known as cosmic dust, are similar to fine soot or sand. However, in the outer regions around a brown dwarf — a starlike object, but one too small to shine brightly like a star — astronomers expected that grains could not grow because the disks were too sparse and particles would be moving too fast to stick together after colliding. Also, prevailing theories say that any grains that manage to form should move quickly toward the central brown dwarf, disappearing from the outer parts of the disk where they could be detected.
“We were completely surprised to find millimeter-sized grains in this thin little disk,” said Luca Ricci of the California Institute of Technology in Pasadena, who led a team of astronomers based in the United States, Europe, and Chile. “Solid grains of that size shouldn’t be able to form in the cold outer regions of a disk around a brown dwarf, but it appears they do. We can’t be sure if a whole rocky planet could develop there, or already has, but we’re seeing the first steps, so we’re going to have to change our assumptions about conditions required for solids to grow.”
ALMA’s increased resolution compared to previous telescopes also allowed the team to pinpoint carbon monoxide gas around the brown dwarf — the first time that cold molecular gas has been detected in such a disk. This discovery and that of the millimeter-sized grains suggest that the disk is more similar to the ones around young stars than previously expected.
Ricci and his colleagues made their finding using the partially completed ALMA in the high-altitude Chilean desert. ALMA is a growing collection of high precision, dish-shaped antennas that work together as one large telescope to observe the universe with groundbreaking detail and sensitivity. ALMA “sees” the universe in millimeter-wavelength light, which is invisible to human eyes. Construction of ALMA is scheduled to finish in 2013, but astronomers began observing with a partial array of ALMA dishes in 2011.
The astronomers pointed ALMA at the young brown dwarf ISO-Oph 102, also known as Rho-Oph 102, in the Rho Ophiuchi star-forming region in the constellation Ophiuchus the Serpent Bearer. With about 60 times the mass of Jupiter but only 0.06 times that of the Sun, the brown dwarf has too little mass to ignite the thermonuclear reactions by which ordinary stars shine. However, it emits heat released by its slow gravitational contraction and shines with a reddish color, albeit much less brightly than a star.
ALMA collected light with wavelengths around a millimeter, emitted by disk material warmed by the brown dwarf. The grains in the disk do not emit much radiation at wavelengths longer than their own size, so a characteristic drop-off in the brightness can be measured at longer wavelengths. ALMA is an ideal instrument for measuring this drop-off and for sizing up the grains. The astronomers compared the brightness of the disk at wavelengths of 0.89 millimeter to 3.2mm. The drop-off in brightness from 0.89mm to 3.2mm was not as steep as expected, showing that at least some of the grains are a millimeter or more in size.
“ALMA is a powerful new tool for solving mysteries of planetary system formation,” said Leonardo Testi from the European Southern Observatory (ESO), a member of the research team. “Trying this with previous generation telescopes would have needed almost a month of observing — impossibly long in practice. But using just a quarter of ALMA’s final complement of antennas, we were able to do it in less than one hour.”
In the near future, the completed ALMA telescope will be powerful enough to make detailed images of the disks around Rho-Oph 102 and other objects. “We will soon be able to not only detect the presence of small particles in disks, but to map how they are spread across the circumstellar disk and how they interact with the gas that we’ve also detected in the disk,” said Ricci. “This will help us better understand how planets come to be.”