More on dark matter<\/strong><\/strong><\/h3> - Who came up with dark matter?<\/a><\/strong><\/em><\/li>
- Dark matter questions answered<\/strong><\/em><\/a><\/li>
- Why do some galaxies have no dark matter?<\/strong><\/em><\/a><\/li> <\/ul> <\/div>
Credit: NASA, ESA, M. Jee and H. Ford (Johns Hopkins University) <\/figcaption> <\/figure> <\/div> <\/div> The stuff that makes up stars and planets, even you and me, may be only a tiny minority of what\u2019s really out there.<\/p>
Astronomers have found signs of a celestial spectre, pulling the strings and invisibly shaping the cosmos \u2013 dark matter<\/a>.<\/p> ![\"Hubble's](\"https:\/\/c02.purpledshub.com\/uploads\/sites\/48\/2020\/04\/Extreme-deep-field-1cc325a-e1661413961493.jpg\")
Planets, stars, galaxies, things that we can see: these account for only a small portion of all matter in the Universe. Credit: NASA; ESA; G. Illingworth, D. Magee, and P. Oesch, University of California, Santa Cruz; R. Bouwens, Leiden University; and the HUDF09 Team <\/figcaption> <\/figure> Though it now forms the fundamental basis of our understanding of how the Universe works, astronomers aren\u2019t actually sure what dark matter is.<\/p>
So why do they have such trust in a substance they cannot find?<\/p>
“The first evidence for dark matter appeared way back in the 1930s,” says Justin Read, a dark matter expert at the University of Surrey. It was galaxies that provided some of the earliest clues.\u00a0<\/p>
At first, astronomers expected galaxies to behave just like bigger versions of the Solar System.<\/p>
As you move out from the Sun, the speed of the planets drops off as the Sun\u2019s gravitational pull wanes.<\/p> ![\"You](\"https:\/\/c02.purpledshub.com\/uploads\/sites\/48\/2020\/08\/GettyImages-1148112202-1-53b2096.jpg\")
You might think that galaxies behave like our Solar System, gravitationally speaking, except they don’t. Credit: MARK GARLICK\/SCIENCE PHOTO LIBRARY <\/figcaption> <\/figure> The innermost planet, Mercury, moves at 47km (29 miles) per second and takes just 88 days to complete one orbit.<\/p>
Meanwhile, the furthest planet, Neptune, moves at 5.4km (3.4 miles) per second and takes nearly 165 years to go around.<\/p>
But galaxies do not behave in the same way. Stars near their edges are rotating at similar speeds to those much closer to the centre.<\/p>
These outer stars are moving so fast that they should be able to escape from the galaxy and fly off on their own.<\/p>
Except they don\u2019t.<\/p>
So astronomers suspect there is some hidden gravitational glue that binds galaxies together and helps keep hold of these fast-moving stars.<\/p>
It\u2019s this astronomical adhesive that\u2019s known as dark matter. So what could dark matter be? Here are some of the possible solutions.<\/p>
A misunderstanding of gravity<\/strong><\/h2> ![\"The](\"https:\/\/c02.purpledshub.com\/uploads\/sites\/48\/2024\/08\/coma-cluster.jpg\")
Studies of the Coma Cluster of galaxies were key to the formation of the theory of dark matter. Credit: CTIO\/NOIRLab\/DOE\/NSF\/AURA. Image Processing: D. de Martin & M. Zamani (NSF NOIRLab) <\/figcaption> <\/figure> The majority of astronomers suspect that dark matter is a physical substance, one that outnumbers ordinary matter by about 5:1.<\/p>
Most often it\u2019s considered a type of particle, one that doesn\u2019t interact with light and so we can\u2019t see it.<\/p>
Instead, we can only sense it by the gravitational influence it exerts on its surroundings, including its ability to help galaxies keep hold of fast-moving stars.<\/p>
An example of this is Fritz Zwicky’s studies of the Coma Cluster of galaxies in the 1930s<\/a>.<\/p> However, there is another school of thought that says that dark matter is a mirage, a misunderstanding of the rules of gravity<\/a>.<\/p> This theory goes by the name of Modified Newtonian Dynamics (MOND).<\/p>
At its heart, MOND argues that gravity works differently on the small scale of a Solar System compared with the much bigger scale of a galaxy.<\/p> ![\"Perhaps](\"https:\/\/c02.purpledshub.com\/uploads\/sites\/48\/2024\/10\/05.iotw2434a.jpg\")
Perhaps gravity operates differently on the scale of large galaxies than it does in planetary systems. Credit: Dark Energy Survey\/DOE\/FNAL\/DECam\/CTIO\/NOIRLab\/NSF\/AURA. Image processing: R. Colombari & M. Zamani (NSF NOIRLab) <\/figcaption> <\/figure> Specifically, it suggests that the strength of gravity doesn\u2019t drop off as quickly in galaxies as it does in planetary systems.<\/p>
That would make the gravity on the edge of galaxies stronger than we\u2019ve been accounting for, which is why the fast-moving stars there don\u2019t go rogue and escape into intergalactic space.<\/p>
Not everyone is convinced, however.<\/p>
“MOND is all but dead in my view,” says Read. “We have evidence that dark matter can be physically moved around.”<\/p>
Read points to the Bullet Cluster as a particularly important piece of evidence. This structure was formed when two separate groups of galaxies collided.<\/p> ![\"14-19](\"https:\/\/c02.purpledshub.com\/uploads\/sites\/48\/2023\/04\/04-hubble-discoveries-cluster-composite-eecde83.jpg\")
Galaxies colliding in the Bullet Cluster. Image shows most of the mass of galaxies is separate from the cluster\u2019s hot gas, which is shown in pink. From this astronomers infer the presence of dark matter in the areas coloured blue. <\/figcaption> <\/figure> The merger heated up the galaxies\u2019 gas, producing copious amounts of X-rays.<\/p>
However, when astronomers mapped the Bullet Cluster\u2019s mass, they found that most of it is separated from the hot gas.<\/p>
During the collision, the gases of both galaxies interacted with each other, and the ensuing friction slowed all the gas down.<\/p>
The dark matter, however, did not.<\/p>
“It passed through itself like a ghost,” Read says. This led to a clear separation between ordinary matter and its shadowy counterpart.<\/p>
MOND isn\u2019t the only alternative astronomers have looked into.<\/p>
Unfindable particles<\/strong><\/h2> ![\"Dark](\"https:\/\/c02.purpledshub.com\/uploads\/sites\/48\/2024\/02\/dark-energy-expansion-universe.jpg\")
Dark energy is the name given to the force accelerating the expansion of the Universe. Credit: Hubble\/NASA <\/figcaption> <\/figure> As well as dark matter, astronomers also suspect another mysterious quantity, dark energy<\/a>, is causing the expansion of the Universe to accelerate.<\/p> Could dark matter and dark energy<\/a> be the same thing?\u00a0<\/p> One idea was that both effects were caused by a \u2018dark fluid\u2019 made of particles with negative mass.<\/p>
It had the added benefit of being able to explain the formation of galaxies and the large-scale structure of the Universe.<\/p>
However, the theory was discarded once astronomers realised that galaxies would be the wrong shape and would have to be moving at close to light speed.<\/p>
Even the idea of dark matter particles with ordinary mass has been beset with problems.<\/p>
For one, we haven\u2019t been able to detect any. It\u2019s not like we haven\u2019t tried.<\/p>
The stuff that makes up stars and planets, even you and me, may be only a tiny minority of what\u2019s really out there.<\/p>
Astronomers have found signs of a celestial spectre, pulling the strings and invisibly shaping the cosmos \u2013 dark matter<\/a>.<\/p> Though it now forms the fundamental basis of our understanding of how the Universe works, astronomers aren\u2019t actually sure what dark matter is.<\/p> So why do they have such trust in a substance they cannot find?<\/p> “The first evidence for dark matter appeared way back in the 1930s,” says Justin Read, a dark matter expert at the University of Surrey. It was galaxies that provided some of the earliest clues.\u00a0<\/p> At first, astronomers expected galaxies to behave just like bigger versions of the Solar System.<\/p> As you move out from the Sun, the speed of the planets drops off as the Sun\u2019s gravitational pull wanes.<\/p> The innermost planet, Mercury, moves at 47km (29 miles) per second and takes just 88 days to complete one orbit.<\/p> Meanwhile, the furthest planet, Neptune, moves at 5.4km (3.4 miles) per second and takes nearly 165 years to go around.<\/p> But galaxies do not behave in the same way. Stars near their edges are rotating at similar speeds to those much closer to the centre.<\/p> These outer stars are moving so fast that they should be able to escape from the galaxy and fly off on their own.<\/p> Except they don\u2019t.<\/p> So astronomers suspect there is some hidden gravitational glue that binds galaxies together and helps keep hold of these fast-moving stars.<\/p> It\u2019s this astronomical adhesive that\u2019s known as dark matter. So what could dark matter be? Here are some of the possible solutions.<\/p> The majority of astronomers suspect that dark matter is a physical substance, one that outnumbers ordinary matter by about 5:1.<\/p> Most often it\u2019s considered a type of particle, one that doesn\u2019t interact with light and so we can\u2019t see it.<\/p> Instead, we can only sense it by the gravitational influence it exerts on its surroundings, including its ability to help galaxies keep hold of fast-moving stars.<\/p> An example of this is Fritz Zwicky’s studies of the Coma Cluster of galaxies in the 1930s<\/a>.<\/p> However, there is another school of thought that says that dark matter is a mirage, a misunderstanding of the rules of gravity<\/a>.<\/p> This theory goes by the name of Modified Newtonian Dynamics (MOND).<\/p> At its heart, MOND argues that gravity works differently on the small scale of a Solar System compared with the much bigger scale of a galaxy.<\/p> Specifically, it suggests that the strength of gravity doesn\u2019t drop off as quickly in galaxies as it does in planetary systems.<\/p> That would make the gravity on the edge of galaxies stronger than we\u2019ve been accounting for, which is why the fast-moving stars there don\u2019t go rogue and escape into intergalactic space.<\/p> Not everyone is convinced, however.<\/p> “MOND is all but dead in my view,” says Read. “We have evidence that dark matter can be physically moved around.”<\/p> Read points to the Bullet Cluster as a particularly important piece of evidence. This structure was formed when two separate groups of galaxies collided.<\/p> The merger heated up the galaxies\u2019 gas, producing copious amounts of X-rays.<\/p> However, when astronomers mapped the Bullet Cluster\u2019s mass, they found that most of it is separated from the hot gas.<\/p> During the collision, the gases of both galaxies interacted with each other, and the ensuing friction slowed all the gas down.<\/p> The dark matter, however, did not.<\/p> “It passed through itself like a ghost,” Read says. This led to a clear separation between ordinary matter and its shadowy counterpart.<\/p> MOND isn\u2019t the only alternative astronomers have looked into.<\/p> As well as dark matter, astronomers also suspect another mysterious quantity, dark energy<\/a>, is causing the expansion of the Universe to accelerate.<\/p> Could dark matter and dark energy<\/a> be the same thing?\u00a0<\/p> One idea was that both effects were caused by a \u2018dark fluid\u2019 made of particles with negative mass.<\/p> It had the added benefit of being able to explain the formation of galaxies and the large-scale structure of the Universe.<\/p> However, the theory was discarded once astronomers realised that galaxies would be the wrong shape and would have to be moving at close to light speed.<\/p> Even the idea of dark matter particles with ordinary mass has been beset with problems.<\/p> For one, we haven\u2019t been able to detect any. It\u2019s not like we haven\u2019t tried.<\/p> A misunderstanding of gravity<\/strong><\/h2>
Unfindable particles<\/strong><\/h2>
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