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Supernovas & Remnants

Supernovas are some of the brightest events in the universe, occasionally outshining entire galaxies at their peak. Many supernovas can be seen from billions of light-years away, and nearby supernovas in past centuries have been visible during the daytime. Today, astronomers distinguish two types of supernova: those involving white dwarfs, and those that are the explosions of very massive stars. Both types are responsible for creating and spreading new elements through space, which are the chemical building blocks for the next generation of stars and planets.

This NASA's Chandra X-ray Observatory image shows glowing material in the Cassiopeia A supernova remnant. The explosions of giant stars seed the cosmos with new chemical elements, providing the raw materials for future stars and planets.

Credit: NASA/CXC/SAO

Explosions in the Sky

In the year 1054 CE, observers around the world recorded a new “star” in the sky, which was briefly bright enough to be seen in the daytime, before fading to invisibility. With the advent of telescopes, astronomers connected this with a strangely shaped cloud of gas they named the Crab Nebula. Today, we recognize the “star” was a supernova, and the Crab Nebula is the supernova remnant.

Supernova explosions come in two distinct flavors:

  • Type Ia supernovas — pronounced “type one a” — involve white dwarfs, which explode if they exceed a maximum mass about 1.4 times the mass of the Sun, known as the Chandrasekhar limit. This can happen either when enough material is dumped on a white dwarf to push it past the Chandrasekhar limit, or when two white dwarfs collide and their combination exceeds the maximum. Because all white dwarfs are subject to the Chandrasekhar limit, Type Ia supernovas explode in very similar ways. That gives the light they produce specific patterns, which means they can be used as cosmic distance markers.

  • Core-collapse supernovas are the explosions of stars greater than 8 times the mass of the Sun. These stars fuse increasingly heavy elements in their core until they reach iron. Beyond that, it takes more energy to keep fusion going than the star can manage, so the core collapses, while the outer layers of the star explode outward. Core-collapse supernovas are very different from each other, since the stars that produce them are diverse. The cores of the most massive stars collapse into black holes, while the middle range of masses leave behind neutron stars.

All types of supernovas produce new elements thanks to fusion during the explosion. Much of the iron in the universe comes from Type Ia supernovas, while many heavier elements came from core-collapse supernovas. The outflow of material from the explosions enriches interstellar space, providing the raw materials for new stars and planets. Many of the ingredients that made Earth — including life — came from supernovas.

The Supernova Group at the Center for Astrophysics | Harvard & Smithsonian has cataloged thousands of supernova “light curves”: the increase and decrease of light emission during and after the explosion. These light curves are helpful for identifying the atoms and molecules present in the supernova, measuring the distance to the supernova, and determining what kind of supernova exploded in the first place. https://www.cfa.harvard.edu/supernova/

 

What’s Left Behind

Supernova explosions are dramatic, but the leftovers are just as interesting from a scientific point of view. These supernova remnants — including the Crab Nebula — contain information about the original system that exploded. They are also hotbeds of activity, containing powerful magnetic fields and hot plasma that can create shock waves in the surrounding material. As a result, supernova remnants are extremely important for understanding the life cycle of stars and physical processes in extreme environments.

With Type Ia supernovas, the exploding stars are completely destroyed. In the case of core-collapse supernovas, however, the remnant also harbors the neutron star or black hole created from the core of the dead star. For example, the Crab Nebula harbors a pulsar, a spinning neutron star that interacts with materials in the supernova remnant. In particular, it creates a disk of hot matter around it and a powerful jet shooting away, which heats up matter around it.