Springe direkt zu Inhalt

Physics Colloquium: Prof. Dr. Thomas A. Jung – Programming electronic and spin states in 2D supramolecular architectures by modifications on the single atomic or molecular level

Sep 23, 2022 | 02:15 PM
Prof. Dr. Thomas Jung

Prof. Dr. Thomas Jung

Supramolecular Architectures

Supramolecular Architectures

Professor Jung will report on the work of his research group "Molecular Nanoscience" at the Paul Scherrer Institute and "Nanolab" at the University of Basel. The laboratories develop surface-supported atomic and molecular systems that have specific electronic or spin states and show a particular advantage of addressability.

Future quantum technologies rely on the understanding of the interaction between different electronic states in atoms or molecules. Surface supported atomic and molecular systems provide a base for such investigations with the particular advantage of addressability. In our work we establish on-surface architectures which exhibit specific electronic or spin states originating from the reduced dimensionality of the self-assembled and atomically precise architectures.

Quantum well arrays, exhibiting band-like electronic states for example, can be produced by the interaction of porous on-surface networks with 2D Shockley-type surface states. These quantum wells have been modified by the adsorption / condensation of Xe atoms. By designing the Xe filling pattern in the array, a quantum breadboard can be realized in remembrance of the breadboards used for testing electronic circuitry.

2D ‘checkerboard’ architectures of magnetic molecules containing different e.g. Fe, Mn spins, exhibit particular magnetic properties and serve as templates for the modification of spins by e.g. ligands. On magnetic substrates their spin state is strongly determined by the substrate and can be selectively switched by ligation to e.g. NH3. On non-magnetic Au(111), we have observed the first example of 2D ferrimagnetic long-range order and remanence due to the RKKY interaction mediated by the surface states of the support.

Self-assembled 2D architectures contribute to our understanding of fundamental interactions involved in confinements and in low dimensional systems.


Time & Location

Sep 23, 2022 | 02:15 PM

Lecture Hall A (room 1.3.14)
Department of Physics
Arnimallee 14
14195 Berlin

Further Information

Host: Prof. Dr. Katharina Franke


  • Nanolab
  • nanophysics
  • nanotechnology
  • Paul Scherer Institut
  • physics colloquium
  • surface science
  • Thomas Jung
  • University of Basel