Quantum computing could change the world.
It could transform medicine, break encryption
and revolutionise communications and artificial
intelligence.
Companies like IBM, Microsoft and Google are
racing to build reliable quantum computers.
China has invested billions.
Recently, Google claimed it had achieved quantum
supremacy – the first time a quantum computer
has outperformed a traditional one.
But what is quantum computing? And how does
it work?
Let’s start with the basics.
An ordinary computer chip uses bits.
These are like tiny switches, that can either
be in the off position – represented by
a zero – or in the on position – represented
by a one.
Every app you use, website you visit and photograph
you take is ultimately made up of millions
of these bits in some combination of ones
and zeroes.
This does great for most things, but it doesn’t
reflect the way the universe actually works.
In nature, things aren’t just on or off.
They’re uncertain.
And even our best supercomputers aren’t
very good at dealing with uncertainty. And
that’s a problem.
Because over the last century, physicists
have discovered when you go down to a really
small scale, things start to get weird.
They’ve developed a whole new field of science
to try and explain why. It’s called quantum
mechanics.
Quantum mechanics is the foundation of physics,
which underlies chemistry, which is the foundation
of biology.
So for scientists to accurately simulate any
of those things, they need a better way of
making calculations that can handle uncertainty.
And that's where quantum computers come in.
Instead of bits, quantum computers use qubits.
Rather than just being on or off, qubits can
also exist in a state called called ‘superposition’,
where they’re both on and off at the same
time, or somewhere on a spectrum between the
two.
Superposition is like a spinning coin, and
it’s one of the things that makes quantum
computers so powerful.
A qubit allows for uncertainty.
If you ask a normal computer to figure its
way out of a maze, it will try every single
branch in turn, ruling them all out individually
until it finds the right one.
A quantum computer can go down every path
of the maze at once. It can hold uncertainty
in its head.
It’s a bit like keeping a finger in the
pages of a choose your own adventure book.
If your character dies, you can go back to
your last decision and make a new one rather
than having to go all the way to the start
of the book.
The other thing that qubits can do is called
entanglement. Normally, if you flip two coins,
the result of the first coin toss has no bearing
on the result of the second one. They’re
independent.
In entanglement, two particles are linked
together, even if they’re physically separate.
If one comes up heads, the other one will
also automatically be heads.
It sounds like magic, and physicists still
don’t fully understand how or why it works.
But in the realm of quantum computing, it
means that you can move information around,
even if it contains uncertainty. You can take
that spinning coin and you can use it to perform
complex calculations.
And if you can string together multiple qubits,
you can solve problems that would take our
best supercomputers millions of years to solve.
Quantum computers aren’t just about doing
things faster or more efficiently.
They’ll let us do things that we couldn’t
even have dreamed of without them.
They have the potential to rapidly accelerate
the development of artificial intelligence.
Google is already using them to improve its
software for self-driving cars. They’ll
also be vital for modelling chemical reactions.
Right now, supercomputers can only analyse
the most basic molecules.
But quantum computers operate using the same
quantum properties as the molecules they’re
trying to simulate.
They should have no problem handling even
the most complicated reactions.
That could mean more efficient products – from
better batteries for electric cars, to cheaper
drugs, and even better solar panels.
Scientists hope that quantum computers could
one day help find a cure for Alzheimer’s
disease.
Quantum computers will find a use anywhere
where there’s a complicated system that
needs to be simulated.
That could be anything from predicting the
financial markets, to improving weather forecasting,
to modelling the behaviour of individual electrons:
using quantum computers to improve our understanding
of quantum physics.
Cryptography will be another key application.
Right now, a lot of encryption rely on the
difficulty of breaking down large numbers
into prime numbers.
This is called factoring, and for classical
computers, it’s slow, expensive and impractical.
But quantum computers can do it easily. And
that could put our data at risk.
There are rumours that intelligence agencies
around the world are already stockpiling vast
amounts of encrypted data in the hope that
they’ll soon have a quantum computer that
can crack it.
The only way to fight back is with quantum
encryption. This relies on the uncertainty
principle – the idea that you can’t measure
something in the quantum realm without influencing
the result.
Quantum encryption keys could not be copied
or hacked. They would be completely unbreakable.
You’ll probably never have a quantum chip
in your laptop or smartphone. There isn't
going to be an iPhone Q.
Quantum computers have been theorised about
for decades, but the reason it’s taken so
long for them to arrive is that they’re
incredibly sensitive to interference.
Almost anything can knock a qubit out of the
delicate state of superposition. As a result,
quantum computers have to be kept isolated
from all forms of electrical interference,
and chilled down to close to absolute zero.
That’s colder than outer space.
They’ll mostly be used by academics and
large businesses, who will probably access
them remotely. It’s already possible for
anyone to access IBM’s quantum computer
via its website – you can even play a card
game with it.
Right now, the best quantum computers have
about 50 qubits.
That’s enough to make them incredibly powerful,
because every qubit you add means an exponential
increase in processing capacity.
But they also have really high error rates,
because of those problems with interference.
They’re powerful, but not reliable. That
means that for now, claims of quantum supremacy
have to be taken with a pinch of salt.
In October 2019, Google published a paper suggesting
it had achieved quantum supremacy – the
point at which a quantum computer can outperform
a classical one.
But its rivals disputed the claim – IBM
said Google had not tapped into the full
power of modern supercomputers.
Most of the big breakthroughs so far have
been in controlled settings, or using problems
that we already know the answer to.
And in any case, reaching quantum supremacy
doesn’t mean quantum computers are actually
ready to do anything useful yet.
Researchers have made great progress in developing
the algorithms that quantum computers will
use.
But the devices themselves still need a lot
more work.
Quantum computing could change the world – but
right now, its future remains uncertain.
