What is a Supernova?
A supernova is one of the most powerful explosions in the universe. It occurs towards the end of a massive star’s life, after it has used up all of its nuclear fuel. Deep in the star’s core, nuclear fusion reactions can no longer continue. With no more outward pressure to counter gravity, the core collapses rapidly inward in a matter of seconds. This triggers a massive shock wave that causes the outer layers of the star to explode outward.
Supernovae release as much energy in just a few seconds as our Sun will in its entire lifetime. The explosion is often so bright that it outshines its host galaxy for a brief period. Different types of supernovae can be hundreds of times more luminous than normal novae.
So in summary, a supernova is the extremely energetic explosion that marks the death of a massive star. Such powerful stellar explosions usually leave something behind.
What is usually left behind after a supernova – a neutron star or black hole
After the outer layers of a massive star are blasted away in a supernova, one of two compact objects is typically left behind in the remnants – a neutron star or a black hole.
A neutron star is an incredibly dense stellar corpse, with more mass than the Sun squeezed into a sphere only 20-30 km wide. It forms when the core of the exploded star is too massive to blow away, but not massive enough to collapse entirely into a black hole.
A black hole is created if the star’s core is heavier than about 3 times our Sun’s mass. This causes the core to collapse beyond the limits of neutron degeneracy pressure, resulting in an object so dense that not even light can escape from within its event horizon.
So in summary, when a massive star goes supernova, it usually leaves behind either a neutron star or black hole at its center. These remnants can provide clues about what happened during the powerful explosion.
The Crab Nebula and its Pulsar
One of the famous supernova remnants is located in our own Milky Way galaxy. Known as the Crab Nebula, it is the remnant of a supernova that was observed by Chinese astronomers in 1054 AD. At the center of this nebula lies one of the first pulsars ever discovered – the Crab pulsar.
A pulsar is a highly magnetized, rapidly rotating neutron star. The Crab pulsar spins 30 times per second, emitting twin beams of radiation from its magnetic poles. Every time the beams sweep through our line of sight, it appears to pulse or blink. This pulsar is so active that it powers the elaborate filaments and wind seen flowing outwards in the Crab Nebula.
Using even a small telescope, you can make out the glowing Crab Nebula and glimpse the pulsar at its heart. Its winds and jets shine brightly, evidence that this is one of the most well-studied and energetic neutron stars in the Milky Way. Located around 6,500 light years away, the Crab Nebula and pulsar provide a nearby example of what’s left after a massive star’s explosive demise.
The Missing Remnants
For a long time, astronomers noticed something strange about supernova remnants. Not all of them appeared to contain a neutron star or pulsar at their center, as was expected based on the Crab Nebula. In many cases, nothing could be detected in the remnants’ cores.
This posed a mystery, as the dense remnants of the exploded stars were thought to remain at the location of the supernovae. Scientists assumed these “missing” objects must be black holes, which are far harder to observe directly than neutron stars. Black holes leave no traces other than their strong gravitational pull on nearby stars and gas clouds.
The lack of a visible remnant at the center of some supernova remnants remained an unsolved puzzle. That is, until an accidental discovery helped provide an unexpected explanation. It revealed how some neutron stars get a powerful “kick” that pushes them far from their birthplaces.
The Accidental Discovery
In 2019, astronomers made an unusual finding while studying a supernova remnant known as G327.1-1.1. Located about 30,000 light years away, it had an unusual protrusion seen extending from its outer edge.
A team used radio telescopes to create a detailed simulation of what may have caused this strange feature. To their surprise, it resembled the trail of an object traveling very fast through space. Their model showed a neutron star receiving a powerful kick from the supernova explosion.
This propelled the neutron star, now a pulsar, away from the center of the expanding debris. As it rushed through gas and dust at over 1,000 km/s, it dragged material along with it to form a 13 light year long “tail”. Over 5,000 years, the pulsar plowed through the remnant until it finally escaped into the surrounding space.
This discovery, made by citizen scientists, was completely accidental. But it provided compelling evidence that some neutron stars do not stay put – they can be accelerated to tremendous speeds, leaving behind telltale trails. This helped explain many of the remnants that seemed to lack a core object.
Properties of the Cannonball Pulsar
Taking a closer look at this runaway pulsar reveals just how fast it is moving. The supernova remnant it fled from has a diameter of about 52 light years. Meanwhile, the “tail” left by the pulsar measures a still sizable 13 light years long.
To put those distances in context, the nearest star to our Sun is Proxima Centauri, located around 4.2 light years away. So this pulsar had to plow through material extending many times the distance between our Solar System and its closest stellar neighbor.
Scientists calculated the pulsar is currently speeding through space at over 1,125 kilometers per second. That’s fast enough to escape the Milky Way galaxy entirely if it maintains this velocity. No wonder it earned the name “cannonball pulsar” – it is rocketing four times faster than the average orbital speed of our Sun in the Milky Way.
The chance discovery of this runaway neutron star revealed how some supernova remnants get their unusual shapes. It also showed that pulsars can receive huge kicks during the explosion, allowing them to later be detected far outside the boundaries of the nebula.
Unanswered Questions
Even with this accidental discovery, many questions remain about the nature of supernovae and the neutron stars they create. Scientists still don’t fully understand how some pulsars manage to reach velocities of over 1,000 km/s.
The mechanics of supernova explosions are incredibly complex, involving forces well beyond our current comprehension. But for an object as massive as a neutron star to be accelerated to such extraordinary speeds requires an immense amount of energy from the blast.
Future research using more powerful telescopes may help uncover clues in the fine details of supernova remnants. By comparing more remnants to detailed simulations, scientists hope to map out what’s really happening in the chaotic final moments of a massive star’s life.
Studying additional runaway pulsars could also lend insights. Every object like this that’s detected helps strengthen or modify existing theories. There may yet be more surprises to uncover in the aftermath of stellar cataclysms like the one that created the Cannonball Pulsar.
In conclusion, the accidental discovery of the Cannonball Pulsar provided a potential explanation for many supernova remnants that seemed to lack a core object. While answering one mystery, it also highlighted how much remains unknown about the mechanics of stellar explosions and the propulsion of neutron stars to tremendous velocities. Only by continuing to make serendipitous finds and advancing our observational capabilities can we hope to solve the persisting puzzle of supernovae and their enigmatic remnants.