• Thermopower measurements reveal strong electronic correlations in magic-angle twisted bilayer graphene.
• These electronic correlations contribute to the entropy of the material.
• The research provides insights into the behavior of electrons in this unique structure.

A recent article in Nature Physics discusses the use of thermopower measurements to study magic-angle twisted bilayer graphene. These measurements reveal strong electronic correlations within the material, offering insights into how these correlations contribute to its entropy. The study focuses on understanding the behavior of electrons in this specific arrangement of graphene layers, with potential implications for condensed-matter physics and quantum physics.

• What: Thermopower measurements revealing strong electronic correlations in magic-angle twisted bilayer graphene and their contribution to entropy.
• Who: Fereshte Ghahari (author), researchers in condensed-matter physics and quantum physics.
• When: Published: 01 May 2025
• Where: Research conducted at Department of Physics & Astronomy, George Mason University, Fairfax, VA, USA.

The article focuses on a specialized area of condensed matter physics, specifically the behavior of electrons in magic-angle twisted bilayer graphene. The use of thermopower measurements as a probe provides a valuable method for understanding the electronic correlations within this material. These insights are important for advancing our knowledge of quantum materials and their potential applications. The mention of related articles like 'Thermopower probes of emergent local moments in magic-angle twisted bilayer graphene' indicates ongoing research in this area.

The Nature Physics article sheds light on the electronic properties of magic-angle twisted bilayer graphene through thermopower measurements. The findings contribute to a deeper understanding of electronic correlations and their influence on the material's entropy. This research is part of a broader effort to explore and potentially utilize the unique quantum properties of these materials.