BBC Science The Theory of (nearly) Everything 2019

SEARCHING FOR DARK MATTER

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When a s tronomer s look at the Univer se on the larges t scales , they see huge clus ter s of gala xies s trung out on

long f ilament s , which border enormous cosmic voids. They e xplain this dis tribution by sug ges ting dark matter

provides a ‘scaffold’ by drawing ordinar y matter together with it s gravit ational influence.

Understand

dark matter with

these terms

ANNIHILATION

The process by which two dark

matter particles come together,

creating a cascade of new

particles. We’re attempting to

detect this with various

experiments around the world

and in space.

GRAVITATIONAL

LENSING

A prediction of Einstein’s

General Theory of Relativity,

which says that mass bends

light. However, astronomers

often see more bending than

the amount of visible material

present would suggest.

NEUTRINO

A small, almost massless

particle created by nuclear

reactions inside the Sun.

Additional neutrinos may be

created by dark matter

annihilations and detecting

them would be a big

breakthrough.

STANDARD MODEL

The recipe book that par ticle

physicists use to explain a lot

of the subatomic world. It

contains rules regarding how

particles interact with forces

and light.

SUPERSYMMETRY

An idea that goes beyond the

Standard Model and says

every ‘normal’ particle has a

supersymmetric partner

particle. The lightest of these

supersymmetric particles could

be responsible for dark matter.

designed to boost the machine’s

power. Hopefully, by colliding

particles with more energy than ever

before, nature may begin to reveal

more secrets of its inner workings.

Q

Could dark matter be

something else?

A

So far we’ve been assuming

t hat da rk matter is ta ngible,

something that truly exists. But what

if it doesn’t? What if it’s a pha ntom – a

symptom of the fact that we don’t

understand gravity properly? That’s

exactly what proponents of a theory

called Modified Newtonian Dynamics

(MOND) advocate.

Remember, one of the original

reasons dark matter was introduced

was to account for the fact that stars in

the Milky Way don’t slow down the

further they are from the galactic

centre, unlike the planets of our Solar

System. But what if there is one rule

for gravity on small scales (such as a

solar system) and another for large

scales (like a galaxy)? While Newton’s

laws of gravity allow us to send people

to t he Moon or spacecraf t to t he

planets, stretching those rules to

regions to where they don’t apply

might explain why we’re puzzled by

the strange motions of stars.

The idea was first put forward by

Israeli physicist Mordehai Milgrom in

1983. He suggested that the strength of
      gravity could become stronger where
      acceleration levels are small. These
      ideas can help to explain some details
      about how gala xies work in ways t hat
      the dark matter theory cannot. But
      there is currently no reason to suspect

that gravity behaves differently on

different scales.

Q

Has dark matter got anything

to do with dark energy?

A

No. Dark energy is the name

given to the mysterious entity

thought to be accelerating the overall

expansion of the Universe – a sort of

anti-gravity. In contrast, dark matter

can be thought of as gravitational glue

that helps bind galaxies and clusters of

galaxies together. We’re literally in the

da rk as to what t hey a re.

Q

How much dark matter is

there?

A

Dark matter completely

dominates the ordinary matter

of which people, planets and stars are

made. Our Milky Way is thought to be

about 90 per cent dark matter and only

10 per cent ‘normal’ matter (baryonic

matter). Of all of the matter in the

Universe, 85 per cent is dark matter

and only 15 per cent is baryonic.

But, according to Einstein’s famous

equation E=mc^2 , mass and energy are

two sides of the same coin. This leads

cosmologists to often talk about the

mass-energy of the Universe – all the

mass and all the energy put together.

In t hese ter ms, t he Universe is 68 per

cent dark energy, 27 per cent dark

matter and just 5 per cent atoms. If we

discount the energy part, the numbers

revert to above – 85 per cent dark

matter, 15 per cent baryonic matter.

by COLIN STUART (@skyponderer)

Colin is a science writer and author, and a Fellow

of the Royal Astronomical Society.

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