Today electronic, optoelectronic and spintronic technologies are still primarily based on conventional semiconductors and metals, whose electronic structure and dynamics are well studied. While their energy dispersions can be complex, their electronic transport characteristics as well as their optical properties are often understood from textbook electronic band models, and their technological potential has been largely exhausted. In the past few years, novel classes of materials have been identified, which might enable a paradigm shift for future electronics. Many of these materials have in common that their itinerant electrons exhibit (pseudo )relativistic behaviour: in graphene, electrons behave as massless Dirac particles, enabling studies of relativistic phenomena “in a pencil trace”. In topological insulators, the electron spin is locked to the electron momentum, since the relativistic spin-orbit coupling defines the character of the relevant band structure. In novel two-dimensional semiconductors, such as transition metal dichalcogenides, strong spin-orbit coupling locks spin and valley degrees of freedom. Finally, spin-orbit coupling at interfaces, surfaces and in nanostructures influences electrical transport and optics and enables novel topological phenomena. The CRC1277 has successfully explored many fundamental properties of these special electronic band structures as well as the emergent relativistic effects they entail or induce. In the second funding period, we will extend the material basis from individual molecules, graphene, carbon nanotubes, superconductors and topological insulators to novel nanotubes of topological insulators, antiferromagnetic systems, two-dimensional crystals of transition metal dichalcogenides, as well as hybrid structures, functionalized surfaces and interfaces of different material systems. In our well-established highly synergistic theory-experiment collaborations, we will identify how tailored relativistic effects can lead to novel electronic, transport, magnetic and optical properties. Key concepts that will be explored range from spin-orbitronics, valleytronics and antiferromagnetic spintronics, over Majorana fermions to Floquet band engineering and lightwave electronics. Besides steady-state phenomena, our focus on dynamical effects of electrons in pseudo-relativistic band structures, between interfaces and at atomic defects, will be strengthened with new cutting-edge techniques. These include experimentally time-, spin- and angle-resolved photoelectron spectroscopy as well as ultrafast nanoscopy, and the latest theory concepts combining ab-initio methods with Green function-based many-body calculations. Building on the breakthroughs achieved so far, we will exploit Dirac-like band structures and strong spin-orbit coupling to test first examples of optoelectronic, lightwave-electronic and spintronic functionalities.

DFG Programme Collaborative Research Centres

International Connection Israel

• A01 - Band structure engineering, interfaces and hybrid structures (Project Heads Bougeard, Dominique ;  Kronseder, Matthias ;  Schuh, Dieter )
• A03 - Simulation of ultrafast processes and high harmonic generation in topological materials (Project Heads Evers, Ferdinand ;  Refaely-Abramson, Sivan ;  Wilhelm, Jan )
• A04 - Terahertz spectroscopy of Dirac Fermion systems (Project Head Ganichev, Sergey )
• A05 - Subcycle dynamics of Dirac fermions in topological insulators (Project Heads Huber, Rupert ;  Huber, Markus A. )
• A07 - Quantum transport and time-dependent dynamics of Dirac fermions (Project Heads Richter, Klaus ;  Urbina, Juan Diego )
• A08 - Topological tubes and wires and their hybrids (Project Heads Back, Christian ;  Kronseder, Matthias ;  Weiss, Dieter )
• A09 - Advanced Spin Transport and Protected Edge States in Graphene-Based Proximity Structures (Project Heads Eroms, Jonathan ;  Fabian, Jaroslav )
• A10 - Local topological transport and dynamics of antiferromagnets (Project Heads Back, Christian ;  Wunderlich, Jörg )
• B02 - Spin-orbit induced dynamics in atomic scale systems (Project Heads Donarini, Andrea ;  Huber, Rupert ;  Repp, Jascha )
• B03 - Spin-orbit coupling in organic semiconductors (Project Heads Bange, Sebastian ;  Lupton, John )
• B04 - Spin-orbit interaction and superconductivity in hybrid 1D-2D van derWaals heterostructures (Project Heads Grifoni, Milena ;  Marganska, Magdalena ;  Paradiso, Nicola ;  Strunk, Christoph )
• B05 - Spin-valley dynamics in monolayer semiconductors and their heterostructures: Optical transport and low-frequency Raman spectroscopy (Project Heads Chernikov, Alexey ;  Schüller, Christian )
• B07 - Interplay of spin-orbit coupling and magnetism in 2D materials (Project Head Fabian, Jaroslav )
• B08 - Spin-orbit effects in the supercurrent response of superconducting heterostructures and Josephson junctions (Project Heads Paradiso, Nicola ;  Strunk, Christoph )
• B09 - Topological phases and spin-orbit effects in driven superconductors (Project Heads Grifoni, Milena ;  Schliemann, John )
• B10 - Ultrafast charge and spin transfer in van-der-Waals heterostructures (Project Heads Gierz-Pehla, Isabella ;  Refaely-Abramson, Sivan )
• B11 - Spin-valley polarized excitonic three-level system for quantum interference in monolayer transition metal dichalcogenides (Project Heads Fabian, Jaroslav ;  Lin, Kai-Qiang ;  Vogelsang, Jan )
• MGK - Integrated Research Training Group (IRTG) (Project Heads Evers, Ferdinand ;  Strunk, Christoph )
• Z01 - Central tasks of the Collaborative Research Centre (Project Head Fabian, Jaroslav )

• A02 - Structure and conductivity of surfaces on topological insulators (Project Heads Ebert, Hubert ;  Giessibl, Franz J. )
• B01 - Proximity induced spin-orbit coupling in atomic and molecular wires on substrates (Project Heads Egger, David ;  Evers, Ferdinand ;  Repp, Jascha )
• B06 - Raman scattering in transition metal dichalcogenides (Project Heads Korn, Tobias ;  Schüller, Christian )

Applicant Institution Universität Regensburg

Participating University Technische Universität München (TUM)

Participating Institution Weizmann Institute of Science

Spokespersons Professor Dr. Jaroslav Fabian, since 7/2023; Professor Dr. Klaus Richter, until 6/2023