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DFG Research Unit 1154 "Towards Molecular Spintronics"
Projects
DFG Research Unit 1154 "Towards Molecular Spintronics" 

DFG Research Unit 1154 „Towards Molecular Spintronics“

Projects:

Project Partners Institution
SP1
  • Part I: Thin films of redox-active high-spin molecules
  • Part II: Monolayers of redox-active high-spin molecules on conducting and ferromagnetic metals: Control of selfassembly and integration into devices
Kersting UL
SP2
  • Part I:Preparation of spin coated thin films and self-assembled monolayers of magnetic transition metal complexes
  • Part II: From the preparation of monomolecular layers to thin films of magnetic transition metal complexes towards their integration into spintronic devices
Rüffer, Lang TUC
SP3
  • Part I + II: Electronic structure, transport, and collective effects in molecular layered systems
Kortus,
Timm
TUF,
TUD
SP4
  • Part I + II: Electron spin resonance and magnetic studies
Kataev,
Klingeler,
Büchner
IFW,
UH
IFW/TUD
SP5
  • Part I: Spin dynamics in single molecules and thin films studied by nuclear probe spectroscopy
Klauss TUD
SP6
  • Part I + II: Scanning tunneling microscopy and spectroscopy of magnetic molecules
Hess,
Hietschold
IFW,
TUC
SP7
  • Part I: Spectroscopic studies of magnetic molecular materials
  • Part II: Spectroscopic studies of magnetic molecular materials and their interfaces
Knupfer,
Zahn
IFW,
TUC
SP8
  • Part I + II:From the preparation of molecular layers and their (magneto-)optical investigation towards laterally stacked devices
Salvan, Zahn, Hiller TUC
SP9
  • Part I: Transport through spin polarized semiconductor/molecule/semiconductor tunnel junctions
  • Part II: Vertical magneto-resistive devices made from hybrid metal/molecules/metal multi-layer systems
Schmidt,
Hess
IFW/TUC
IFW

 

SP1. | SP2. | SP3. | SP4. | SP5. | SP6. | SP7. | SP8. | SP9. | [close]

SP3: Electronic structure, transport, and collective effects in molecular layered systems

Based on ab-initio density functional theory results, we will study charge and spin transport both in the scanning tunnelling microscopy geometry and in semiconductor/molecular layer/semiconductor structures. We will employ two complementary approaches: the non-equilibrium Green-function method and the quantum master equation. In the longer term, we plan to also consider collective effects in molecular layers and their relevance for magnetic and transport properties.