The apparent inner calm of quantum materials

Transitions between different phases of matter are part of our day-to-day lives: when water freezes, for example, it passes from liquid to solid state. Some of these transitions may be of a different kind, resulting from so-called topological excitations that force all the particles to act in unison.

Researchers from the University of Geneva(UNIGE) and the CEA,CNRS and UGA have been studying BACOVO – a one-dimensional quantum material unknown to the general public – in collaboration with scientists from the neutronic centers ILL and PSI. They have discovered in this material a novel topological phase transition, governed not by a single type of topological excitation, but by two different ones. In addition, they were able to choose which of the two sets would dominate the other. You can read all about their research in Nature Physics.

The researchers drew on the work of the 2016 Nobel Prize for physics  awarded to David Thouless, Duncan Haldane, and Michael Kosterlitz. The three physicists predicted that a set of topological excitations in a quantum material is likely to induce a phase transition. Numerous theories  have  been  developed  about  these  topological  excitations,  including the feasibility of combining two of them in a single material. But is that a real possibility? And if so, what would happen? The teams from UNIGE and CEA, CNRS and UGA were able to provide the first experimental confirmation of the theory predicting the existence of two simultaneous sets of topological excitations and the competition between them. All in all, it is a small revolution in the mysterious world of quantum properties.

Theory and experimentation intimately linked

The researchers from CEA, CNRS, and Université Grenoble Alpes were working on a one-dimensional antiferromagnetic material with particular  properties:  BACOVO  (BaCo₂V₂O₈).  “We  performed  various experiments  on  BACOVO,  an  oxide  characterised  by  its  helical  structure,”  underline  Béatrice  Grenier,  Sylvain  Petit  and  Virginie  Simonet,  researchers at the CEA, CNRS and UGA. “But our experimental results evidenced a puzzling phase transition” – which is why their team called on Thierry Giamarchi, a professor in the Department of Quantum Matter Physics in UNIGE’s Faculty of Science. The Geneva physicist explains: “Based on their results, we established theoretical frameworks capable  of  interpreting  them.  These  theoretical  models were then  tested again using new experiments so they could be validated.

Creating the “standard model”

The aim was to understand how BACOVO’s quantum properties act, especially  their  topological  excitations.  “For  this  purpose,  we  used  neutron scattering, meaning we sent a neutron beam onto the material.  The  neutrons  behave  like  small  magnets  that  interact  with  those of BACOVO, according to a strategy “disturb in order to reveal”, helping us to understand their properties,” says Quentin Faure, Ph-D student  at  the  Institute  for  Nanoscience  and  Cryogenics  (CEA/UGA)   and  Néel  Institute.  When  the  model  developed  at  UNIGE  matches  the experiment, it becomes the material’s “standard model”. Professor Giamarchi enthusiastically points out: “And, in fact, the model we established  with  Shintaro  Takayoshi  predicted  exactly  the  outcome seen in the experiment!”

A material with unexpected properties

But this experiment also led to a discovery that the scientists had not anticipated. “After settling on the “standard model” for BACOVO, we observed unexpected properties,» says Shintaro Takayoshi, researcher in the Department of Quantum Matter Physics in UNIGE’s Faculty of Science. When placed in a magnetic field, BACOVO develops a second set of topological excitations that are in competition with the first one, confirming theories from the 1970s and 1980s organised around the field opened up by the work of the Nobel scientists. “As well as proving the existence of this confrontation between two sets of topological excitations within the same material – an unprecedented event – we were able to experimentally control which set would dominate the other”, adds the Genevan researcher. And that is a first!

What was originally a theoretical hypothesis became a verified experiment. The in-depth analysis of BACOVO undertaken by the physicists proved that two sets of topological excitations come into direct confrontation in the same material and control the state of matter, which differs according to the dominant set, yielding a quantum phase transition. Furthermore, the scientists succeeded in controlling which set prevails, meaning they could adjust BACOVO’s state of matter at will. “These results open up a whole range of possibilities in terms of quantum physics research,” concludes Professor Giamarchi. “It’s true that we are still at the fundamental level, but it’s through this kind of discovery that we are getting closer every day to applications for the quantum properties of materials... and why not quantum computers!?”

Re.: Nature Physics (2018). doi:10.1038/s41567-018-0126-8

Contact: Béatrice Grenier, ILL

About the University of Geneva (UNIGE)

Founded in 1559 by Jean Calvin, the University of Geneva (UNIGE) is dedicated to thinking, teaching, dialogue and research. With 16’500 students of more than 150 different nationalities, it is Switzerland’s second largest university.

UNIGE offers UNIGE offers more than 500 programmes (including 129 Bachelor’s and Master’s degree programmes, 80 doctoral programmes) and more than 300 continuing education programmes covering an extremely wide variety of fields: exact sciences, medicine, humanities, social sciences, law, etc. Its domains of excellence in research include life sciences (molecular biology, bio-informatics), physics of elementary particles, and astrophysics. Just like the city of Geneva itself, the university enjoys a strong international reputation, both for the quality of its research (it ranks among the top institutions among the League of European Research Universities) and the excellence of its education.

About the Université Grenoble Alpes (UGA)

The Université Grenoble Alpes (UGA) is the result of a merger in 2016 of Grenoble’s three universities. The UGA, is a comprehensive, global university, offering academic programs and supporting research in all major disciplines: Science, Technology, and Health Sciences; Law, Economics and Business; Humanities and Social Sciences; and Arts, Literature and Languages. International relations are in the frontline of our global university, which is open to the world and part of a diverse and growing network of partnerships. The UGA’s traditions – of innovation,  diversity and excellence – are embodied in our expertise in education, creating a welcoming environment for students, faculty, and staff. 
Our academic programs are designed to provide the necessary skills for those who wish to broaden their horizons, whether to meet the challenges of today’s world or to compete in the international job market.
Innovation and excellence also enrich and sustain our world-class research, making the most of an exceptional scientific environment with strong ties to business and industry. Our community of researchers includes experts from all over the world, who work across a large variety of disciplines in the service of knowledge and the spirit of inquiry.