Waterloo-led experiment achieves the strongest coupling between light and matter
Researchers at the University of Waterloo’s Institute for Quantum Computing (IQC) recorded an interaction between light and matter 10 times larger than previously seen
Researchers at the University of Waterloo’s Institute for Quantum Computing (IQC) recorded an interaction between light and matter 10 times larger than previously seenBy Media Relations
The strength of the interaction between photons and a qubit was so large that it opens the door to a realm of physics and applications unattainable until now.
The results appear in the paper, “Ultrastrong coupling of a single artificial atom to an electromagnetic continuum in the nonperturbative regime,” published in Nature Physics.
“We are enabling the investigation of light-matter interactions in a new domain in quantum optics,” said Pol Forn-Diaz, a postdoctoral fellow at IQC and lead author of the paper. “The possibilities are exciting because our circuit could potentially act as a quantum simulator to study other interesting quantum systems in nature.”
The ultrastrong coupling between photons and qubits may lead to the exploration of new physics related to biological processes, exotic materials such as high-temperature superconductors, and even relativistic physics.
To conduct their experiment, the researchers fabricated aluminum circuits in the University of Waterloo’s Quantum NanoFab, and then cooled them in dilution refrigerators to a temperature as low as one per cent of a degree above absolute zero. The circuits become superconducting at these cold temperatures, meaning that they can carry a current without resistance or losing energy. These aluminum circuits, known as superconducting qubits, obey the laws of quantum mechanics and can behave as artificial atoms.
To control the quantum state of a superconducting circuit, the researchers sent photons using microwave pulses into the superconducting circuit and applied a small magnetic field through a coil inside the dilution refrigerator. By measuring the photon transmission, the researchers could define the resonance of the qubit, indicated by the reflection of the photons off the qubit. Usually, the qubit resonance is centered around a very narrow range of frequencies.
This illustration shows a qubit attached to a waveguide where light in the form of microwaves enters and exits.
“We measured a range of frequencies broader than the qubit frequency itself,” said Forn-Diaz. “This means there is a very strong interaction between the qubit and the photons. It is so strong that the qubit is seeing most of the photons that propagate in the circuit, which is a distinctive signature of ultrastrong coupling in an open system.”
This work was carried out in a collaboration between the Waterloo-based experimental groups of Adrian Lupascu and Christopher Wilson. Both are faculty members in the departments Physics and Astronomy and Electrical and Computer Engineering, as well as IQC. The other authors of this work from IQC are Jean-Luc Orgiazzi, Muhammet Ali Yurtulan, PhD students, and Ron Belyansky, undergraduate research assistant. The project was carried out in collaboration with Juan Jose Garcia-Ripoll, PhD, from the Instituto de Física Fundamental in Madrid, Spain, and Borja Peropadre, PhD, from Harvard University.