Agência FAPESP, April 13, 2026 -- So-called “exotic phases of matter” are currently a major focus of scientific research. There are two reasons for this. From the perspective of basic science, they represent a largely unexplored frontier of quantum physics. From the perspective of applied science, they are the foundation of emerging technologies, including robust quantum computing.

A recent study by an international team of researchers revealed that the heavy fermion compound CeRu₄Sn₆ exhibits an entirely new electronic state: a topological semimetal stabilized not in spite of, but thanks to, quantum criticality. An article on the subject was published in Nature Physics.

“The work expands the repertoire of exotic phases of matter and suggests that quantum critical points may act as ‘nurseries’ for strongly correlated topological states,” says Julio Larrea Jiménez, a physicist, professor at the University of São Paulo’s Physics Institute (IF-USP) in Brazil, co-founder and head of the institute’s Laboratory for Quantum Matter under Extreme Conditions (LQMEC), and one of the authors of the paper.

Topological materials are those whose electronic properties are protected by symmetries; small impurities, deformations, or fluctuations cannot easily destroy the global quantum state. Interest in this type of material is understandable, as topology can protect the quantum state against local perturbations. This could be useful for storing and handling quantum information with less decoherence, which is a major challenge for developing quantum computing.

According to Larrea, the breakthrough of the study was the experimental demonstration that sophisticated symmetries associated with nontrivial topologies, such as chirality, can produce quantum states different from those studied nearly a century ago using the Schrödinger equation. It is worth noting that, in addition to previously known states, there are others conditioned by the action of unusual symmetries on the system.

“The way electrons organize themselves in a material – the so-called ‘trivial topology’ generated by conventional symmetries – is typically described using Bloch states. In metallic materials, the interactions between electrons are usually explained using the concept of quasiparticles. But in the heavy-fermion compound CeRu₄Sn₆, in a state of genuine quantum criticality, these quasiparticles simply cease to exist. Surprisingly, however, we find the emergence of a topological semimetal in this extreme regime,” says Larrea.

To understand this phenomenon, the authors studied a theoretical model of a semimetal at the critical point where the Kondo effect is destroyed. This model shows that topological crossings can emerge in the electronic bands even without well-defined quasiparticles, created by the system’s own quantum fluctuations.

“Under normal conditions, the CeRu₄Sn₆ system exhibits entanglement between conduction electrons and electrons in the cerium 4f shell – the so-called Kondo effect. But when subjected to extreme conditions of pressure, magnetic field, and temperatures near absolute zero, this entanglement breaks down, and the material reaches a quantum critical point at which quantum fluctuations dominate the entire dynamics. It’s at this limit that the new topological phase emerges,” comments Larrea.

In this scenario, the researchers observed the spontaneous Hall effect in the CeRu₄Sn₆, which is the appearance of a transverse voltage without an external magnetic field. This type of response is typical of Weyl semimetals. In the theoretical model proposed in the article, the team considered a Weyl-Kondo semimetal at the Kondo breakdown limit when quantum fluctuations become so intense that they dissolve the heavy fermion fluid. However, rather than dismantling the electronic structure entirely, these fluctuations generated new types of topological crossings.

Larrea emphasizes that the core focus of the study was to combine interactions and symmetries. “Our experiment provided the first empirical demonstration of a process that had previously been predominantly theoretical,” he summarizes.

In the critical region, the traditional model of well-defined quasiparticles and an order parameter that defines a thermodynamic state breaks down. The new work showed that a topological state can emerge precisely where the electronic bands become “unruly” and low-energy excitations “replace” the order parameter. This occurs not in spite of quantum criticality, but as a direct product of it.

In recent years, topology has become a new language of physics. States protected by topological symmetries are robust against perturbations and can explain phenomena that previously seemed unrelated. This line of research was recognized in 2016 when David Thouless, Duncan Haldane, and Michael Kosterlitz were awarded the Nobel Prize in Physics “for theoretical discoveries of topological phase transitions and topological phases of matter.”

From an experimental standpoint, extreme pressures, temperatures on the order of millikelvins, intense magnetic fields, and 2D materials enable the creation of unprecedented quantum states. This opens up territories that were previously inaccessible to experimentation. It has also shown that there are far more possibilities for the quantum organization of matter than previously thought. This makes exotic phases a major conceptual challenge and a highly promising path for new technologies.

The new study falls within this broad field. FAPESP supported it through a Young Investigator Grant awarded to Larrea.