Description du projet
Une recherche sonde les phases topologiques dans les systèmes fortement corrélés
Les phases topologiques de la matière sont l’un des domaines les plus passionnants de la physique de la matière condensée. Ces états exotiques présentent des propriétés électroniques inhabituelles, telles qu’une magnétorésistance extrêmement forte et un effet Hall anomal, susceptibles d’être exploitées dans l’électronique et l’informatique quantique du futur. Financé par le programme Actions Marie Skłodowska-Curie, le projet TopoPress vise à étudier l’interaction entre les corrélations électroniques fortes et les phases topologiques non triviales dans les composés à base de cérium. Les résultats du projet permettront d’améliorer considérablement la compréhension des systèmes électroniques fortement corrélés et des matériaux topologiques.
Objectif
The discovery of topological phases of matter has driven the attention of great part of the solid-state science community due to its high for future applications, led by the presence of unusual electronic properties, such as extreme large magnetoresistance and anomalous Hall effect. However, topological phases on Ce-based nonsymmorphic materials are rather unexplored. The nonsymmorphic crystalline structure may create band crossings, which are needed for the existence of non-trivial topological phases, while the presence of magnetic Ce ions gives rise to many complex effects, such as magnetism and the Kondo effect. These correlated phenomena result in a promising route to pin the band crossings of nonsymmorphic compounds close to the Fermi level, favoring non-trivial topological effects in transport properties, which may lead to the realization of new spintronic devices. This proposal aims to understand the interplay between strong electronic correlations and non-trivial topological phases in Ce-based compounds. To achieve that hydrostatic pressure and/or uniaxial stress will be used to tune the electronic bands, i.e. moving the band crossings towards the Fermi energy and/or modify the bandstructure, and the magnetic correlations in Ce-based nonsymmorphic compounds, such as CeAlGe and CeSbTe. By performing electrical transport experiments under applied pressure/stress and in magnetic fields, the evolution and interrelation between non-trivial topological phases and strong electronic correlations will be investigated. As part of the experimental work, a new technique will be developed, which combines micro-structured samples with Bridgman or diamond anvil cells. This method will enable the simultaneous realization of magnetoresistance and Hall measurements up to more than 30 GPa. Our findings will significantly enhance the knowledge in strongly correlated electrons systems and topological materials, two fundamental areas of condensed matter physics.
Champ scientifique
Mots‑clés
Programme(s)
Régime de financement
MSCA-IF - Marie Skłodowska-Curie Individual Fellowships (IF)Coordinateur
80539 Munchen
Allemagne