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Electron Spin Resonance Scanning Tunneling Microscope of Non-Magnetic Molecules

Electron Spin Resonance-Scanning Tunneling Microscopy (ESR-STM) of C60 radical ion on graphene is a first demonstration on radical ions. ESR-STM signal at g=2.00 was measured in accordance with macroscopic ESR of fullerene radical ion. The ESR-STM signal was bias voltage dependent, as it reflects the charge state of the molecule. The signal appears in the bias voltage which enables the ionization of the lowest unoccupied molecular orbital (LUMO) (creation of radical anion) and the highest occupied molecular orbital (HOMO (creation of a radical cation) of the C60 molecule when it deposited on graphene. The linewidth provides information on the lifetime of the free radical. In several experiments, a 13C hyperfine splitting was observed, and a change in the phase of the ESR-STM peak as a function of the speed of the magnetic field sweep was changed. This might be used to provide information on the relaxation times of the molecules. In parallel, ESR-STM signal at g=1.6 was ascribed to Tungsten oxide (W5+) at the tip apex, which is not bias voltage dependent. The ability of ESR-STM to explore non paramagnetic molecules, significantly broadens the scope of this technique.

preprint2022arXivOpen access
Zion HazanMichael AverbukhYishay Manassen
cond-mat.mes-hall
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Zion HazanMichael AverbukhYishay Manassen

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