Well what is special is… we, as a species, basically just invented (in the last 10 years or so) the ability to measure gravitational waves, that is to say, fluctuations in the fabric of spacetime itself, that reverberate outward from gravitationally extreme events such as a black hole merger.

Further… I am fairly sure this is the first time we have been able to ‘view’ or ‘see’ or ‘witness’ a blackhole merger with such gravitational wave detecting technology.

So… imagine being the first person to look at the sun with a properly bandwidth blocking lense or system, such that you can see in much more detail the surface, now you can see coronal loops.

https://en.wikipedia.org/wiki/Coronal_loop

Similar to that, being able to ‘view’ a black hole merger with our new gravity wave ‘lenses’ gives us a whole bunch of useful information we did not have before.

That and uh, as far as I know, black hole mergers are just not very common, in general.

But… we really wouldn’t know that for sure, on account of being… you know, black holes, kinda hard to see directly, prior to gravity wave detectors, and other very recently developed imaging techniques, we had to figure out they existed by calculating how light bends around them before it gets to us, and then work backwards to figure out where they are, or just ‘huh, a bunch of stuff seems to be orbiting around… nothing?’

We have not been able to directly observe them until fairly recently, even just as far back as the 90s, when I was a kid, a fair amount of astrophysicists were still in the ‘they’re just theoretical and we can’t actually definitively prove they exist’ camp.

Like, it wasn’t untill 2018 that we had the first actual direct image of a blackhole, Messier 87’s supermassive blackhole.