how we did it and why it’s historic

A major breakthrough in quantum technology was achieved in October 2024: the first-ever quantum satellite communication link between China and South Africa. The connection spanned a remarkable 12,900km: the longest intercontinental quantum communication link established to date. The longest before this was 7,600km and within the northern hemisphere only.

It was achieved with quantum key distribution, a method for a sender and receiver to share a secure key that they can use to safely send messages. Any interception during transmission leaves traces that can be detected. It involves sending single photons (tiny particles of light).

If someone tries to intercept the photons, the photons get disturbed because of quantum physics. Quantum physics is the study of matter and energy at the most fundamental level. Sender and receiver use only undisturbed photons, making the key to the message ultra secure. The key can be sent via optical fibre or free-space, including satellites.

Quantum communication can be used to send data in many sectors such as the government, military and financial sectors.

I’m part of the group of quantum physics researchers who created a secure, real-time quantum link between Beijing in China and Stellenbosch University in South Africa. It’s the first quantum satellite link in the southern hemisphere. It’s also the first secure quantum communication between the northern and southern hemispheres.

The connection enabled the secure transmission of encrypted images, relying on the unique principles of quantum physics.

With this achievement, South Africa has joined the frontier of quantum communication. It’s a step towards an eventual fully integrated, secure and global quantum internet.

What we achieved

As researchers, we are interested in developing optical systems to deploy quantum communication links.

Our primary focus is on satellite-based quantum communication. Satellite links are vital for developing a secure quantum communication network since they work over distances of several thousand kilometres. Fibre networks on the ground have distance limitations.

We design instruments (optical payloads) capable of generating and detecting entangled photons in orbit.

Read more:
Quantum entanglement: what it is, and why physicists want to harness it

Our work bridges quantum optics, aerospace engineering and communication theory to realise scalable, high-performance quantum links between ground stations and satellites.

To set up quantum communication links between China and South Africa, a microsatellite called Jinan 1 was launched into low Earth orbit, and a portable optical ground station was set up. This is basically a movable device equipped with a powerful telescope and special detectors that detect the encoded photons sent from the satellite.

The ultra-secure quantum satellite link between China and South Africa was achieved during a single pass of the satellite over the optical ground station. It was not only the longest quantum satellite link but also the most secure that’s been achieved. The key, the undisturbed photons, consisted of 1.07 million bits (units of data).

An operating superconducting quantum computer.
Yuan Bing / CFOTO/Future Publishing via Getty Images

Why this matters

Traditional secure communication methods rely on mathematical algorithms and the computational difficulty of solving certain problems, such as factoring large numbers. In contrast, quantum communication draws its security from the fundamental laws of physics. Such laws include the no-cloning theorem. It states that it is impossible to make an exact copy of an unknown quantum state and that the observer effect (measurement disturbance) of measuring a quantum state changes it. This makes eavesdropping detectable.

Quantum key distribution allows two parties to share encryption keys in a way that detects any attempt at eavesdropping. The keys are encoded using quantum states, typically single photons, and transmitted through optical fibres or free-space links. While fibre-based systems suffer from signal loss over long distances, satellites offer a promising solution by operating in the low-loss environment of the upper atmosphere and outer space.

Quantum satellite communication is a step towards building a global quantum internet – an interconnected network that enables secure communication, quantum computing, and sensing across continents.

The success of Jinan-1 points the way towards networks of quantum microsatellites, making secure global communication a real possibility.

Read more:
Light is the science of the future – the Africans using it to solve local challenges

Moving forward

There are major opportunities for both industry and policymakers.

For businesses, especially in sectors like finance, defence and healthcare, these links enable ultra-secure communication systems that are resistant to hacking even from future quantum computers. This allows companies to protect and communicate sensitive data.

For policymakers, it presents a chance to strengthen national security, and set global standards for responsible use. Similarly, investment in research and education to build a skilled workforce.

It also encourages international cooperation, as countries work together to create a secure communication network.

Overall, quantum satellite links could reshape how the world communicates, making privacy and security more reliable than ever before.

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