Nanostructured functional materials are the backbone of modern and sustainable technologies, such as batteries, fuel cells, and solar cells. Their performance is determined by the simultaneous transport of ions, molecules, electrons, and heat in and between the functional materials. For confinements that reach nanometre length scales, multiple interactions occur between the carrier types, the structured materials, and the accompanying interfaces. These interrelated interactions have been poorly understood so far. The flow of ions, molecules, electrons, and heat is no longer independent of each other and can deviate strongly from the bulk behavior. Therefore, the CRC aims to elucidate, fundamentally understand, and control the transport behavior of these four carrier types in nanostructured functional materials. This includes strategies to program materials to guide multiple transport species together, independently of each other or in spatially different directions. These signature properties of multiple transport are key to transform the technologies mentioned above. The CRC will conduct this research along the guiding themes i) electrolyte-host systems, ii) interface-controlled systems, and iii) percolating networks addressing major carrier type combinations and confinement interactions. Using systematic nanostructuring and chemical modification of well-chosen material classes, we investigate the influence of 1D to 3D confinements on the transport of the carrier types across multiple length and time scales. We, thereby, span a controlled parameter space, which enables a comprehensive analysis of confinement-controlled transport. The CRC brings together an interdisciplinary team of scientists rooted in physics, chemistry, and engineering. Its members contribute expertise in synthesis, processing, characterization, and theory. We promote their collaboration by establishing a Transport Academy, which guides the synergistic work within the team, the exchange with the international community and the education of young researchers. It integrates a research training group to equip our students with the necessary competencies for successful scientific work and future careers. The CRC is driving the digital transformation with a dedicated project on research data management. It will provide a metadata environment that facilitates a seamless analysis across the projects. Combining the team-driven meta-analyses with the exchange at cross-disciplinary, international meetings, we aim to establish an innovative research philosophy for the CRC. We follow the vision to enable a knowledge-driven material design that can simultaneously control the transport of ions, molecules, electrons, and heat in nanostructured materials with an increasing level of adaptiveness and responsivity to external triggers. This paves the way for decisively improving existing and exploring new technologies for today's grand challenges in energy, mobility, and sustainability.

DFG Programme Collaborative Research Centres

• A01 - 1D, 2D and 3D self-supporting objects based on functionalised porous polymers for fast ion conduction (Project Heads Agarwal, Seema ;  Senker, Jürgen )
• A02 - Proton and water transport in functionalised porous electrode structures (Project Heads Kempe, Rhett ;  Roth, Christina )
• A03 - Oriented growth and oriented transport of ions in aligned pores (Project Heads Marschall, Roland ;  Schenk, Anna Sophia )
• A04 - Transport mechanisms of electrolytes under the influence of nanoscale confinements (Project Heads Senker, Jürgen ;  Vogel, Michael )
• A05 - Directional ionic conductivity in two-dimensionally confined structures (Project Heads Breu, Josef ;  Papastavrou, Georg )
• B01 - Correlated ion and electron transport in Li-ion battery cathode materials (Project Heads Bianchini, Matteo ;  Oberhofer, Harald )
• B02 - Electron transfer in semiconductor electrodes with immobilized 3d metal complexes for photoelectrochemical water oxidation (Project Heads Kümmel, Stephan ;  Marschall, Roland ;  Weber, Birgit )
• B03 - Controlling ion and electron transport in hybrid perovskites confined in mesoporous matrices (Project Heads Grüninger, Helen ;  Herzig, Eva M. )
• B04 - Nanostructured hybrid perovskite films by aerosol-based cold deposition for controlled ion and electron transport (Project Heads Köhler, Anna ;  Moos, Ralf )
• B05 - Control of charge transport in hybrid 2D perovskite heterostructures with organic semiconducting and ion-conducting interlayers (Project Heads Herink, Georg ;  Kühne, Alexander )
• C01 - Anisotropic thermal transport in layered hybrid materials (Project Heads Breu, Josef ;  Retsch, Markus )
• C02 - Thermal transport in 2D layered chalcogenide-based heterostructures (Project Heads Friedrich, Daniel ;  Pauly, Fabian )
• C03 - Probing electron and heat conductivities on a local scale (Project Head Papastavrou, Georg )
• C04 - Modulation of electron and thermal transport in nanostructured blend / copolymer systems by thermomechanical control (Project Heads Greiner, Andreas ;  Ruckdäschel, Holger )
• C05 - Thermal and electronic transport in hierarchically structured fibrous nonwovens (Project Heads Greiner, Andreas ;  Retsch, Markus )
• INF - Integrating a digital work environment for sustainable data management (Project Heads Martin, Thomas ;  Oberhofer, Harald )
• MGK - Integrated Research Training Group “Transport in Structured Materials” (Project Heads Bianchini, Matteo ;  Weber, Birgit )
• Z - Central tasks of the Collaborative Research Centre (Project Head Senker, Jürgen )

Applicant Institution Universität Bayreuth

Participating University Technische Universität Darmstadt; Universität Augsburg; Universität Ulm

Spokesperson Professor Dr. Jürgen Senker