Chao Li, Vladislav Pokorný, Martin Žonda, Jung-Ching Liu, Ping Zhou, Outhmane Chahib, Thilo Glatzel, Robert Häner, Silvio Decurtins, Shi-Xia Liu, Rémy Pawlak, Ernst Meyer
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Nanoscale Control of Quantum States in Radical Molecules on Superconducting Pb(111)
Magnetic impurities on superconductors present a viable platform for building
advanced applications in quantum technologies. However, a controlled
manipulation of their quantum states continues to pose a significant challenge,
hindering the progress in the field. Here we show the manipulation of magnetic
states in the radical molecule 4,5,9,10-tetrabromo-1,3,6,8-tetraazapyrene
(TBTAP) on a Pb(111) superconducting surface using low-temperature scanning
tunneling microscopy. Tunneling spectra reveal Yu-Shiba-Rusinov (YSR) states
near the Fermi energy in isolated molecules. A quantum phase transition from
singlet to doublet ground state is induced by changing the tip-molecule
distance. Additionally, the presence of a second TBTAP molecule allows tuning
of the YSR state position by altering the relative distance and can induce
splitting of the YSR states for certain orientations. The construction of
molecular chains up to pentamers shows periodic arrangements of charged and
neutral molecules, with even-numbered chains forming a charged dimer structure
at one end. Information can be encoded in these chains by switching the dimer
position. These findings elucidate interactions between molecular assemblies
and superconducting substrates, paving the way for advanced quantum-state
engineering.