In a new breakthrough, researchers at the University of Copenhagen, in collaboration with Ruhr University Bochum, have solved a problem that has caused quantum researchers headaches for years. The researchers can now control two quantum light sources rather than one. Trivial as it may seem to those uninitiated in quantum, this colossal breakthrough allows researchers to create a phenomenon known as quantum mechanical entanglement. This in turn, opens new doors for companies and others to exploit the technology commercially.

Going from one to two is a minor feat in most contexts. But in the world of quantum physics, doing so is crucial. For years, researchers around the world have strived to develop stable quantum light sources and achieve the phenomenon known as quantum mechanical entanglement - a phenomenon, with nearly sci-fi-like properties, where two light sources can affect each other instantly and potentially across large geographic distances. Entanglement is the very basis of quantum networks and central to the development of an efficient quantum computer.

Researchers from the Niels Bohr Institute published a new result in the highly esteemed journal Science, in which they succeeded in doing just that. According to Professor Peter Lodahl, one of the researchers behind the result, it is a crucial step in the effort to take the development of quantum technology to the next level and to "quantize" society's computers, encryption and the internet.

"We can now control two quantum light sources and connect them to each other. It might not sound like much, but it's a major advancement and builds upon the past 20 years of work. By doing so, we've revealed the key to scaling up the technology, which is crucial for the most ground-breaking of quantum hardware applications," says Professor Peter Lodahl, who has conducted research the area since 2001.

The magic all happens in a so-called nanochip - which is not much larger than the diameter of a human hair - that the researchers also developed in recent years.

Quantum sources overtake the world's most powerful computer
Peter Lodahl's group is working with a type of quantum technology that uses light particles, called photons, as micro transporters to move quantum information about.

While Lodahl's group is a leader in this discipline of quantum physics, they have only been able to control one light source at a time until now. This is because light sources are extraordinarily sensitive to outside "noise", making them very difficult to copy. In their new result, the research group succeeded in creating two identical quantum light sources rather than just one.

"Entanglement means that by controlling one light source, you immediately affect the other. This makes it possible to create a whole network of entangled quantum light sources, all of which interact with one another, and which you can get to perform quantum bit operations in the same way as bits in a regular computer, only much more powerfully," explains postdoc Alexey Tiranov, the article's lead author.

This is because a quantum bit can be both a 1 and 0 at the same time, which results in processing power that is unattainable using today's computer technology. According to Professor Lodahl, just 100 photons emitted from a single quantum light source will contain more information than the world's largest supercomputer can process.

By using 20-30 entangled quantum light sources, there is the potential to build a universal error-corrected quantum computer - the ultimate "holy grail" for quantum technology, that large IT companies are now pumping many billions into.

Other actors will build upon the research
According to Lodahl, the biggest challenge has been to go from controlling one to two quantum light sources. Among other things, this has made it necessary for researchers to develop extremely quiet nanochips and have precise control over each light source.

With the new research breakthrough, the fundamental quantum physics research is now in place. Now it is time for other actors to take the researchers' work and use it in their quests to deploy quantum physics in a range of technologies including computers, the internet and encryption.

"It is too expensive for a university to build a setup where we control 15-20 quantum light sources. So, now that we have contributed to understanding the fundamental quantum physics and taken the first step along the way, scaling up further is very much a technological task," says Professor Lodahl.

The research was conducted at the Danish National Research Foundation's "Center of Excellence for Hybrid Quantum Networks (Hy-Q)" and is a collaboration between Ruhr University Bochum in Germany and the the University of Copenhagen's Niels Bohr Institute.

Research Report:Collective super- and subradiant dynamics between distant optical quantum emitters

Related Links
University of Copenhagen - Faculty of Science
Computer Chip Architecture, Technology and Manufacture
Nano Technology News From SpaceMart.com

Tweet

Thanks for being here; We need your help. The SpaceDaily news network continues to grow but revenues have never been harder to maintain. With the rise of Ad Blockers, and Facebook - our traditional revenue sources via quality network advertising continues to decline. And unlike so many other news sites, we don't have a paywall - with those annoying usernames and passwords. Our news coverage takes time and effort to publish 365 days a year. If you find our news sites informative and useful then please consider becoming a regular supporter or for now make a one off contribution.
SpaceDaily Contributor $5 Billed Once credit card or paypal		SpaceDaily Monthly Supporter $5 Billed Monthly paypal only

This chilling effect on stacked chips could ignite computing at the edge
Washington DC (SPX) Jan 26, 2023
As the future of microsystems technology converges around three-dimensional heterogeneous integration (3HDI) microelectronics, the scientists, researchers, and engineers working to advance the state of the art - including at DARPA - are arriving at the same challenge: How can we pack the maximum computing into the smallest-possible space, and how can we manage the heat inherently generated by high-powered processing, especially in such a small space? There's increasing recognition that 3DHI - whic ... read more