This bizarre state of matter is called a quantum spin liquid and, contrary to the name, has nothing to do with everyday liquids like water. Instead, it’s all about magnets that never freeze and the way electrons in them spin. In regular magnets, when the temperature drops below a certain temperature, the electrons stabilize and form a solid piece of matter with magnetic properties. In quantum spin liquid, the electrons don’t stabilize when cooled, don’t form into a solid, and are constantly changing and fluctuating (like a liquid) in one of the most entangled quantum states ever conceived.

The different properties of quantum spin liquids have promising applications that can be used to advance quantum technologies such as high-temperature superconductors and quantum computers. But the problem about this state of matter has been its very existence. No one had ever seen it — at least, that had been the case for almost 50 years.

Today, a team of Harvard-led physicists said they have finally experimentally documented this long sought-after exotic state of matter. The work is described in a new study in the journal Science and marks a big step toward being able to produce this elusive state on demand and to gain a novel understanding of its mysterious nature.

“It is a very special moment in the field ,” said Mikhail Lukin, the George Vasmer Leverett Professor of Physics, co-director of the Harvard Quantum Initiative (HQI), and one of the senior authors of the study. “You can really touch, poke, and prod at this exotic state and manipulate it to understand its properties. …It’s a new state of matter that people have never been able to observe.”

The learnings from this science research could one day provide advancements for designing better quantum materials and technology. More specifically, the exotic properties from quantum spin liquids could hold the key to creating more robust quantum bits — known as topological qubits — that are expected to be resistant to noise and external interference.

“That is a dream in quantum computation,” said Giulia Semeghini, a postdoctoral fellow in the Harvard-Max Planck Quantum Optics Center and lead author of the study. “Learning how to create and use such topological qubits would represent a major step toward the realization of reliable quantum computers.”

The research team set out to observe this liquid-like state of matter using the programmable quantum simulator the lab originally developed in 2017. The simulator is a special kind of quantum computer that allows the researchers to create programmable shapes like squares, honeycombs, or triangular lattices to engineer different interactions and entanglements between ultracold atoms. It is used to study a host of complex quantum processes.

The idea of using the quantum simulator is to be able to reproduce the same microscopic physics found in condensed matter systems, especially with the freedom that the programmability of the system allows.

“You can move the atoms apart as far as you want, you can change the frequency of the laser light, you can really change the parameters of nature in a way that you couldn’t in the material where these things are studied earlier,” said study co-author Subir Sachdev, the Herchel Smith Professor of Physics and current Maureen and John Hendricks Distinguished Visiting Professor at the Institute for Advanced Study. “Here, you can look at each atom and see what it’s doing.”

In conventional magnets, electron spins point up or down in some regular pattern. In the everyday refrigerator magnet, for example, the spins all point toward the same direction. This happens because the spins usually work in a checker box pattern and can pair so that they can point in the same direction or alternating ones, keeping a certain order.

Quantum spin liquids display none of that magnetic order. This happens because, essentially, there is a third spin added, turning the checker box pattern to a triangular pattern. While a pair can always stabilize in one direction or another, in a triangle, the third spin will always be the odd electron out. This makes for a “frustrated” magnet where the electron spins can’t stabilize in a single direction.

“Essentially, they’re in different configurations at the same time with certain probability,” Semeghini said. “This is the basis for quantum superposition.”

The Harvard scientists used the simulator to create their own frustrated lattice pattern, placing the atoms there to interact and entangle. The researchers were then able to measure and analyze the strings that connected the atoms after the whole structure entangled. The presence and analysis of those strings, which are called topological strings, signified that quantum correlations were happening and that the quantum spin liquid state of matter had emerged.

The work builds on earlier theoretical predictions of Sachdev and his graduate student, Rhine Samajdar, and on a specific proposal by Ashvin Vishwanah, a Harvard professor of physics, and Ruben Verresen, an HQI postdoctoral fellow. The experiment was done in collaboration with the lab of Markus Griener, co-director of the Max Planck-Harvard Research Center for Quantum Optics and George Vasmer Leverett Professor of Physics, and scientists from the University of Innsbruck and QuEra Computing in Boston.

“The back-and-forth between theory and experiment is extremely stimulating,” said Verresen. “It was a beautiful moment when the snapshot of the atoms was taken and the anticipated dimer configuration stared us in the face. It is safe to say that we did not expect our proposal to be realized in a matter of months.”

After confirming the presence of quantum spin liquids, the researchers turned to the possible application of this state of matter to creating the robust qubits. They performed a proof-of-concept test that showed it may one day be possible to create these quantum bits by putting the quantum spin liquids in a special geometrical array using the simulator.

The researchers plan to use the programable quantum simulator to continue to investigate quantum spin liquids and how they can be used to create the more robust qubits. Qubits, after all, are the fundamental building blocks on which quantum computers run and the source of their massive processing power.

“We show the very first steps on how to create this topological qubit, but we still need to demonstrate how you can actually encode it and manipulate it,” Semeghini said. “There’s now a lot more to explore.”