Subj : Rogue black holes might be neither rogue nor black holes
To   : All
From : PopularScience-Physics
Date : Sat Sep 23 2023 00:45:48

Rogue black holes might be neither rogue nor black holes

Date:
Sun, 26 Jun 2022 17:00:00 +0000

Description:
Hubble data from the Milky Way and other galaxies is helping astronomers get 
to the bottom of an otherwise invisible mystery. NASA/ESA and G. Bacon 
(STScI) Millions of invisible black holes float freely around our galaxy. Now 
astronomers think they can spot them. The post Rogue black holes might be 
neither rogue nor black holes appeared first on Popular Science .

FULL STORY
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Hubble data from the Milky Way and other galaxies is helping astronomers get 
to the bottom of an otherwise invisible mystery. NASA/ESA and G. Bacon 
(STScI) 

When a star 20 times as massive as our sun dies, it can explode in a 
supernova and squeeze back down into a dense black hole (with gravitys help). 
But that explosion is never perfectly symmetrical, so sometimes, the 
resulting black holes goes hurtling off into space. These wandering objects 
are often called rogue black holes because they float around freely, 
untethered by other celestial bodies. 

But that name might be a misnomer, according to Jessica Lu , associate 
professor of astronomy at the University of California Berkeley. She prefers 
the term free-floating to describe these black holes. Rogue, she says, 
implies that the nomads are rare or unusualor up to no good. 

Thats certainly not the case. Astronomers estimate that there are as many as 
100 million such black holes that roam around our galaxy. But because theyre 
solitary, theyre extremely difficult to find. Until recently, these so-called 
rogue black holes were only known through theory and calculations. 

They are ghosts, so to speak, says Lu, who has made it her mission to find 
the Milky Ways free-floating black holes. 

 [Related: Were still in the dark about a key black hole paradox ] 

Earlier this year, two teams of space researchers separately revealed 
detections of what just might be one of these roaming black holes. One of 
those teams was led by Casey Lam , a graduate student in Lus lab. The other 
was led by Kailash C. Sahu , an astronomer at the Space Telescope Science 
Institute. Both teams posted their papers on an open-access website without 
expert review. 

The scientists will get more data from the Hubble Space Telescope in October 
that Lu says should help resolve the mystery of whether this is a black hole 
or a neutron star. Theres still a lot of uncertainty about how stars die and 
the ghost remnants that they leave behind, she notes. When stars much more 
massive than our sun run out of nuclear fuel, theyre thought to collapse into 
either a black hole or a neutron star. But we dont know exactly which ones 
die and turn into neutron stars or die and turn into black holes, adds Lu. We 
dont know when a black hole is born and a star dies, is there a violent 
supernova explosion? Or does it directly collapse into a black hole and maybe 
just give a little burp? 

With star stuff making up everything we know in the world, understanding the 
afterlife of stars is key to understanding how we, ourselves, came to be. How 
to spot a black hole on the loose 

Black holes are inherently invisible. They trap all light that they 
encounter, therefore theres nothing for the human eye to perceive. So 
astronomers have to get creative to detect these dense, dark objects. 

Typically, they look for anomalies in gas, dust, stars, and other material 
that might be caused by the intensely strong gravity of a black hole. If a 
black hole is tearing material away from another celestial body, the 
resulting disk of debris that surrounds the black hole can be brightly 
visible. (Thats how astronomers took the first direct image of one in 2019 
and an image of the black hole at the center of the Milky Way earlier this 
year.) 

But if a black hole is not inflicting chaos with its gravitational force, 
theres hardly anything to detect. Thats often the case with these moving 
black holes. So astronomers like Lu use another technique called astrometric 
or gravitational microlensing . 

What we do is we wait for the chance alignment of one of these free-floating 
black holes and a background star, Lu explains. When the two align, the light 
from the background star is warped by the gravity of the black hole [in front 
of it]. It shows up as a brightening of the star [in the astronomical data]. 
It also makes it take a little jaunt in the sky, a little wobble, so to 
speak. 

The background star doesnt actually moverather, it appears to shift off its 
course when the black hole or another compact object passes in front of it. 
Thats because the gravity of the black hole warps the fabric of spacetime, 
according to Albert Einsteins General Theory of Relativity , which alters the 
starlight. 

The odds that a roaming black hole could pass through our celestial 
neighborhood and disrupt life on Earth are astronomically small. 

Astronomers use microlensing to study all kinds of temporary phenomena in the 
universe, from supernovae to exoplanets transiting around their stars. But 
its tricky to do with ground-based telescopes, as the Earths atmosphere can 
blur the images. 

In astrometry, youre trying to measure the position of something very 
precisely, and you need very sharp images, Lu explains. So astronomers rely 
on telescopes in space, like Hubble, and a couple of ground-based instruments 
that have sophisticated systems to adapt for the atmospheric interference. 
There are really only three facilities in the world that can make this 
astrometric measurement, Lu says. Were working right at the cutting edge of 
what our technology can do today. The first rogue black hole? 

It was that brightening, or a gravitational lensing event as Lu calls it, 
that both her and Sahus teams spotted in data from the Hubble Space Telescope 
in 2011. Something, they surmised, must be passing in front of that star. 

Figuring out what caused the wobble and change of intensity in a stars light 
requires two measurements: brightness and position. Astronomers observe that 
same spot in the sky over time to see how the light changes as the object 
passes in front of the star. This gives them the data they need to calculate 
the mass of that object, which in turn determines whether its a black hole or 
a neutron star. 

We know the thing thats doing the lensing is heavy. We know its heavier than 
your typical star. And we know that its dark, Lu notes. But were still a 
little uncertain about exactly how heavy and exactly how dark. If its only a 
little bit heavy, say, one and a half times the mass of our sun, it might 
actually be a neutron star. But if its three to 10 times as massive as our 
sun, then it would be a black hole, Lu explains. 

As the two teams gathered data from 2011 to 2017, their analyses revealed 
distinctly different masses for that compact object. Sahus team determined 
that the roaming object has a mass seven times that of our sun, which would 
put it squarely in black hole territory. But Lam and Lus team calculated it 
to be less massive, somewhere between 1.6 and 4.4 solar masses, which spans 
both possibilities. 

 [Related: Black holes can gobble up neutron stars whole ] 

The astronomers cant be sure which calculation is correct until they get a 
chance to know just how bright the background star is normally and its 
position in the sky when something isnt passing in front of it. They werent 
focused on that star before noticing its uncharacteristic brightness and 
wobble, so theyre just now getting the chance to make those baseline 
observations as the lensing effect has faded, Lu explains. Those observations 
will come from new Hubble data in the fall. 

What they do know is that the object in question is in the Carina-Sagittarius 
spiral arm of the Milky Way galaxy, and is currently about 5,000 light years 
away from Earth. This detection also suggests that the nearest roaming black 
hole to could be less than 100 light years away, Lu says. But thats not 
reason for concern. 

Black holes are a drain. If you get close enough, they will consume you, Lu 
points out. But you have to get very close, much closer than I think we 
typically picture. The boundary around a black hole marking the line where 
light can still escape its gravity, called the event horizon, typically has a 
radius of under 20 miles. 

The odds that a roaming black hole could pass through our celestial 
neighborhood and disrupt life on Earth are astronomically small, Lu says. 
Thats the size of a city. So a black hole could pass by the solar system and 
wed hardly notice. 

But shes not ruling it out. Im a scientist, she says. I cant say no chance. 

Regardless of whether the first teams detected a roaming black hole or a 
neutron star, Lu says, the real revolution that these two papers are showing 
is that we can now find these black holes using a combination of brightness 
and position measurements. This opens the door to discoveries of more 
light-capturing nomads, especially as new telescopes come online, including 
the Vera C. Rubin Observatory currently under construction in Chile and the 
Nancy Grace Roman Space Telescope scheduled to launch later this decade. 

The way Lu sees it, the next chapter of black hole studies in our galaxy has 
already begun. 

The post Rogue black holes might be neither rogue nor black holes appeared 
first on Popular Science . Articles may contain affiliate links which enable 
us to share in the revenue of any purchases made.



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Link to news story:
https://www.popsci.com/science/what-are-rogue-black-holes/


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