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by Tibi Puiuby
February 13, 2025
from
ZmeScience Website
Illustration by Midjourney.
The future of
computing
might not be
one giant
quantum machine
but many linked
together...
Physicists at the University of Oxford have taken a significant step
toward solving one of the most daunting challenges in quantum
computing:
how to connect multiple quantum processors to
work together seamlessly.
Their breakthrough showcases a new method for
distributing quantum computations across two separate modules linked
by a photonic network.
This achievement could be a crucial milestone in
the quest to build large-scale practical quantum computers.
Quantum computers promise to revolutionize fields like,
cryptography, drug discovery, and materials
science by solving problems that are currently intractable for
classical computers.
But building a quantum computer with enough
working qubits - the quantum equivalent of bits - to tackle these
problems has proven extraordinarily difficult.
One major hurdle is maintaining the delicate
quantum states of qubits while scaling up the system.
But what if you could connect multiple smaller quantum computers?
Think of it as a quantum version of a computer
network, where each module is like a separate computer, and the
photons act as the cables linking them together.
This is the first demonstration of distributed
quantum computing.
The Quantum Network That Could
Dougal Main and Beth Nichol
working on the
distributed quantum computer.
Credit John
Cairns.
A truly powerful quantum computer would need to process millions of
qubits.
The world's most powerful quantum computer, IBM's
22-foot-wide, 15-foot-high Quantum System Two, operates using
a 1,121-qubit chip called
Condor.
A qubit, or quantum bit, is the fundamental
unit of information in a quantum computer.
Unlike classical bits, which can be either 0
or 1, a qubit can exist in a superposition of both states at the
same time.
This ability comes from the strange rules of
quantum mechanics, where,
particles like electrons or photons don't
just have a single state but can occupy multiple
possibilities until measured...
A famous analogy is
Schrödinger's cat - both alive and
dead until observed.
This property allows quantum computers to process
vast amounts of information in parallel, potentially solving complex
problems exponentially faster than traditional computers.
But superposition is only part of what makes qubits powerful.
They also rely on
entanglement, a phenomenon
Albert Einstein famously called,
"spooky action at a distance."
When two qubits become entangled, their
states remain linked no matter how far apart they are...
Squeezing hundreds of thousands or millions of
qubits into a single machine, however, presents immense challenges.
Instead of cramming more qubits into one device,
Oxford's approach is different:
network smaller quantum computers together...
In theory, there is no upper limit to how many
processors can be linked.
Each module in the new system contains a handful of trapped-ion
qubits, held in place by electric fields.
These qubits, tiny carriers of quantum
information, are connected by optical fibers rather than
traditional wiring.
Instead of electrical signals, they
communicate using photons, particles of light that can travel
between the modules.
This arrangement is key because it allows for
entanglement between different quantum modules.
With
entanglement, the Oxford team used
a method called quantum teleportation to perform logical operations
across the separate processors.
Until now,
teleportation has mainly been
used to transfer quantum states - essentially, information encoded
in a single qubit.
This new study (Distributed
Quantum Computing across an Optical Network Link) takes
it further, teleporting logical gate, the basic building blocks of
quantum computation itself.
"Previous demonstrations of quantum
teleportation have focused on transferring quantum states
between physically separated systems," said Dougal Main,
the study's lead author.
"In our study, we use quantum teleportation
to create interactions between these distant systems."
This approach mirrors how traditional
supercomputers work.
By linking smaller units, they achieve
capabilities far beyond what any single unit could manage.
In some ways, the concept mirrors how
traditional supercomputers work.
Instead of a single powerful processor,
supercomputers rely on thousands of smaller computing units
working in parallel.
For quantum computing, this strategy sidesteps
the engineering hurdles of packing more qubits into a single device
while preserving the delicate quantum properties essential for
accurate calculations.
"By interconnecting the modules using
photonic links, the system gains valuable flexibility," Main
said.
"Modules can be upgraded or swapped out
without disrupting the entire architecture."
A Glimpse of the Quantum Internet?
The ability to link quantum processors over a network hints at a
future "quantum
internet," where distant quantum devices could form an
ultra-secure network for communication, sensing, and computation.
To demonstrate the power of their system, the researchers ran
Grover's search algorithm, a
quantum method that can search large, unstructured datasets far
faster than classical computers.
This experiment showed that network-distributed
quantum information processing is feasible with current technology.
While the results are promising, the journey to large-scale quantum
computing is far from over. The Oxford team's work is a proof of
concept, showing that distributed quantum computing is possible.
But scaling up will require overcoming
significant technical hurdles, from improving the stability of
qubits to refining the photonic links that connect them.
"Scaling up quantum computers remains a
formidable technical challenge," said Professor David Lucas,
principal investigator of the study.
"It will likely require new physics insights
as well as intensive engineering effort over the coming years."
Yet, the blueprint is there.
Instead of a single quantum leviathan, the future
may belong to networks of smaller, interconnected machines:
a web of quantum minds, working as one...!
The findings (Distributed
Quantum Computing across an Optical Network Link)
appeared in the journal
Nature.
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