Astronomers often witness stars and planets being eaten by bigger stars and by black holes. It’s cannibalism on a cosmic scale, and not for the faint of heart.
A star like our Sun will burn steadily for billions of years, providing a serene environment for its orbiting planets. But, when such stars exhaust their thermonuclear fuels, they shed their outer layers and their cores collapse to form White Dwarfs, objects about the size of Earth but with masses comparable to our Sun. That’s the fate of the least-massive 95% of all stars, including our Sun. A single teaspoon of White Dwarf would “weigh” 30 tons. Gravity on its surface could be up to one million times greater than on Earth, and its surface temperature could be up to 250,000 °F, 25 times our Sun’s current temperature.
Planets orbiting too close to these stars may be consumed.
Astronomers reported this month observing four White Dwarfs that have planet guts running down their chins—spectral lines of iron, nickel and sulfur, elements typically found not in stellar atmospheres but in the cores of terrestrial planets like Earth. One of these stars is now consuming an estimated one thousand tons of planet guts every second.
While iron and nickel may be tasty, they are rare delicacies in our universe. Truly mammoth appetites require more readily available fare. How about helium? The images below show a galaxy 2.7 billion light-years away (one light-year is six trillion miles). The two images on the left were taken in 2009, and the two images on the right are from 2010. The upper image pair was taken in ultra-violet (UV) light and the lower pair in visible light. The images show that the central black hole of this galaxy consumed the helium core of a star. The image is brightest in UV because the helium gas became very hot as it fell into the black hole at 20 million mph. Astronomers think we may be seeing the dessert course; the star may have passed near the black hole many years ago when its hydrogen gas was eaten during the entree course. Helium is heavier than hydrogen, thus it sinks to the star’s center and is more tightly held. The outer hydrogen layer is much easier for the black hole to strip off and gulp down. The mass of this black hole is estimated to be three million times our Sun’s mass.
Galaxy PS1-10jh: 2009 left, 2010 right, UV upper, optical lower
M31, Andromeda Galaxy