![]() ![]() ( Credit: NASA’s Goddard Space Flight Center)īefore we ever saw our first gravitational wave, we already knew a fair bit about both neutron stars and black holes. These particles emit radiation in jets, and as the neutron star rotates, a serendipitously configured pulsar will see its jets point at Earth once per revolution. This computer simulation of a neutron star shows charged particles being whipped around by a neutron star’s extraordinarily strong electric and magnetic fields. Here’s how we learned what’s truly out there in the Universe. There was only ever a gap in our observations. But with the latest data release bringing us up to nearly 100 total gravitational wave events, we can now finally see what many had suspected all along: there is no mass gap, after all. ![]() Even after the first and second major data releases, this mass gap, perhaps puzzlingly, still persisted. ![]() By detecting the ripples in spacetime that emerged from the inspiral and merger of these very objects - black holes and neutron stars - we could infer the nature and masses of both the pre-merger and post-merger objects that resulted. Starting in 2015 with the twin LIGO detectors, however, a fundamentally new type of astronomy was born: gravitational wave astronomy. This in-between region, puzzlingly, was known as the “mass gap.” While neutron stars seemed to top out at around twice the mass of the Sun, the least massive black holes didn’t appear until we got up to around five solar masses. While both neutron stars and black holes were thought to have formed by the same mechanism - the core-collapse of a massive star’s central region during a supernova event - observations only revealed low-mass neutron stars and black holes whose masses were significantly higher. How massive can the most massive neutron star be, and how light can the lightest black hole be? For the entire history of astronomy up until 2015, our understanding of both of these phenomena was limited. ![]()
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