X-rays reveal uneven allotment of element made by blowup
JPL-Caltech, CXC/SAO and NASA
Giant stars are slightly off-kilter as they go kablooey, research in the Feb. 20 Nature suggests.
When massive stars run out of elements to fuse in their core, they collapse under their own gravity; the imploding material then bounces off the core and explodes in a bright display known as a core-collapse supernova. But computer simulations indicate that if material collapses symmetrically, as scientists long assumed, a star would not explode.
To address this conundrum, a team including Caltech astrophysicist Brian Grefenstette pointed NASA’s recently launched Nuclear Spectroscopic Telescope Array at Cassiopeia A, the remnant of a nearby core-collapse supernova whose light first reached Earth about 350 years ago. The researchers plotted the spatial distribution of high-energy X-rays emitted during the decay of the radioactive element titanium-44, which is forged in the depths of supernova explosions.
The X-rays revealed that the titanium is