News & Media


May 30, 2018

Paradoxically, environmental noise helps preserve the coherence of a quantum system

Quantum computers promise to lead to major advances in certain areas of complex computing. One of the roadblocks to achieving such dream computers, however, is the fact that quantum phenomena, which take place at the level of atomic particles, can be severely affected by environmental “noise” from their surroundings. In the past, scientists have tried to maintain the coherence of the systems by cooling them to very low temperatures, for example, but challenges remain. Now, in research published in Nature Communications, scientists from the RIKEN Center for Emergent Matter Science and collaborators have shown, with a three-particle system, that they can use dephasing—a process that normally would reduce the coherence—to paradoxically maintain it.

Quantum phenomena are generally restricted to the atomic level, but there are cases—such as laser light and superconductivity—where the coherence of quantum phenomena allows them to be expressed at the macroscopic level. This is important for the development of quantum computers. However, they are also extremely sensitive to the environment, which destroys the very coherence that makes them meaningful.

The group, led by Seigo Tarucha of the RIKEN Center for Emergent Matter Science, set up a system of three quantum dots in which electron spins could be individually controlled with an electric field. They began with two entangled electron spins in one of the end quantum dots, while keeping the center dot empty, and transferred one of these spins to the center dot. They then swapped the center dot spin with a third spin in the other end dot using electric pulses, so that the third spin was now entangled with the first, which was not in contact with it. What was surprising, however, was that the entanglement was stronger than expected, and based on simulations, they realized that the environmental noise around the system was, paradoxically, helping the entanglement to form.The semiconductor devices for the experiment were grown usingmolecular beam epitaxy at the Ruhr-University Bochum, Germany.

According to Takashi Nakajima, the first author of the study, “We discovered that this derives from a phenomenon known as the ‘quantum Zeno paradox’ or ‘Turing paradox,’ which means that one can slow down a quantum system by the mere act of observing it frequently. This is interesting as it leads to the environmental noise, which normally makes a system incoherent, actually making it more coherent.”

According to Tarucha, the leader of the team, “This is a very exciting finding, as it could potentially help to accelerate research into scaling up semiconductor quantum computers, allowing us to solve scientific problems that are very tough on conventional computer systems.”

Nakajima continues, “Another area that is very interesting to me is that a number of biological systems, such as photosynthesis, that operate within a very noisy environment take advantage of macroscopic quantum coherence, and it is interesting to ponder if a similar process may be taking place.”


  • Takashi Nakajima, Matthieu R. Delbecq, Tomohiro Otsuka, Shinichi Amaha, Jun Yoneda, Akito Noiri, Kenta Takeda, Giles Allison, Arne Ludwig, Andreas D. Wieck, Xuedong Hu, Franco Nori and Seigo Tarucha, "Coherent transfer of electron spin correlations assisted by dephasing noise", Nature Communications, 10.1038/s41467-018-04544-7


Group Director
Seigo Tarucha
Quantum Functional System Research Group
RIKEN Center for Emergent Matter Science

Jens Wilkinson
RIKEN International Affairs Division
Tel: +81-(0)48-462-1225 / Fax: +81-(0)48-463-3687

Experimental setup

Schematic showing how an entangled state is transferred in an array of four spin qubits