In a recent Nature Physics article, ICFO researchers present photothermoelectric nanoscopy as an innovative tool for identifying strong electron correlations in twisted 2D materials with nanometer-level spatial precision, revealing key details that traditional methods had previously missed. The work is done in collaboration with Princeton University, University of Oxford, Donostia International Physics Center, National Institute for Materials Science, IKERBASQUE, and University of Notre Dame.
In quantum physics, when a large number of electrons are brought together under carefully tailored external conditions, they start to behave collectively, showing strong correlations that can give rise to superconductivity, correlated insulators, or exotic forms of ferromagnetism, among others. This naturally occurs in twisted two-dimensional materials —one-atom-thick layers stacked with a slight rotation between them—, which have consequently become convenient platforms to study these correlated behaviors.
In the quest for uncovering the most intricate and fundamental details of correlated quantum phenomena, ICFO researchers Dr. Sergi Batlle Porro, Dr. Roshan Krishna Kumar, Dr. Niels C. H. Hesp, Dr. Petr Stepanov, led by ICREA Prof. Frank Koppens, have recently presented a novel tool in Nature Physics called photothermoelectric nanoscopy. Showcased with twisted symmetric trilayer graphene (three graphene layers, with a 1.5º twist between the middle one and the others), the technique identified strong electron correlations that cannot be accounted for by conventional semiconductor models. This study was conducted together with Princeton University, University of Oxford, Donostia International Physics Center, National Institute for Materials Science (Tsukuba, Japan), IKERBASQUE, and University of Notre Dame.
Photothermoelectric nanoscopy works by focusing infrared light onto a minuscule nanoscale hot spot on the sample. Due to the so-called Seebeck effect, this temperature rise generates a voltage, which can then be mapped with nanometer precision. “We recorded a highly unusual thermoelectric response, a clear indicator of correlated physics,” explains Dr. Sergi Batlle Porro, first author of the article. Ultimately, they obtained an exceptionally detailed depiction of how strong correlations emerge and evolve in twisted 2D materials, including how different twist angles and interaction strengths affect its behavior, thereby uncovering key information that was unattainable with previous methods.
The experimental results were especially consistent with the heavy-fermion model. According to this framework, some electrons in twisted trilayer graphene behave as if they had a much larger mass, which prevents them from freely moving and contributing to the electrical current, while others are mobile and conduct current. “This disparity is not seen in typical semiconductors,” shares Dr. Batlle. “In fact, it facilitates strong interactions, which can lead to exotic quantum phenomena.” The collaborative theory team from Princeton had predicted that these phenomena can be probed through the Seebeck effect, which turned out to be an accurate prediction.
The team also found that the correlated behavior appears over a wide range of angles, between roughly 1.30° and 1.55°, offering a much broader window compared to other commonly used platforms such as twisted bilayer graphene. “With these less stringent engineering conditions, trilayer graphene emerges as an attractive, adjustable platform for studying correlated phases,” claims ICREA Prof. Frank Koppens, lead researcher of the study.
Now, the researchers would like to adapt photothermoelectric nanoscopy for use at temperatures below one Kelvin (better suited for detecting exotic quantum phenomena) and to apply it to other twisted 2D materials, which might host similar heavy-fermion-like behaviours.
Source:
Article referenced:
Batlle Porro, S., Călugăru, D., Hu, H. et al. Photovoltage microscopy of symmetrically twisted trilayer graphene. Nat. Phys. (2025).
DOI: https://doi.org/10.1038/s41567-025-03071-9
