| Popis: |
Recent experiments on magic-angle twisted bilayer graphene (MATBLG) indicate an unusual coexistence of heavy and light electrons, characteristic of Heavy-Fermion physics. Yet, these experiments lack direct evidence of the existence of local moments associated with the heavy electrons, a key component of Heavy-Fermion physics. Thermopower serves as a sensitive probe for measuring entropy and can, therefore, unveil the presence of local moments by assessing their impact on entropy. In this work, we have carried out comprehensive thermopower studies on MATBLG by varying temperatures ($T$) and magnetic fields ($B$). While the resistance exhibits prominent resistance peaks at integer fillings apart from the Dirac point (DP, $\nu = 0$) and full band filling ($\nu = \pm 4$), the thermopower remains featureless and symmetric to the DP with opposite signs, in complete violation of the Mott formula, even up to $\sim 100K$. This discrepancy indicates that resistance and thermopower are carried by different kinds of carriers. With the expected sign changes at the DP and full band filling, the thermopower demonstrates additional sign changes within the conduction and valence bands around $\nu \sim \pm 1$, persisting from $5K$ to $50K$. These observations cannot be explained solely by thermopower arising from an emergent Heavy-Fermion band picture, which is highly sensitive to temperature. Instead, our data is consistent with the dominant contribution coming from the entropy of the localized moments of heavy electrons. To validate the claim, we studied the thermopower with $B_{\parallel}$ and $B_{\perp}$, revealing a $30\%$ and $50\%$ reduction, respectively, and attributed to the partial polarization of the local moments (spin/valley), resulting in decreased entropy. Our results highlight the thermopower contribution from local moments and establish the Heavy-Fermion physics in MATBLG. |
