2018
DOI: 10.1103/physrevlett.121.196803
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Tuning the Coupling of an Individual Magnetic Impurity to a Superconductor: Quantum Phase Transition and Transport

Abstract: The exchange scattering at magnetic adsorbates on superconductors gives rise to Yu-Shiba-Rusinov (YSR) bound states. Depending on the strength of the exchange coupling, the magnetic moment perturbs the Cooper pair condensate only weakly, resulting in a free-spin ground state, or binds a quasiparticle in its vicinity, leading to a (partially) screened spin state. Here, we use the flexibility of Fe-porphin (FeP) molecules adsorbed on a Pb(111) surface to reversibly and continuously tune between these distinct gr… Show more

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Cited by 131 publications
(128 citation statements)
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“…48 This ground state spin configuration can be altered by slight differences in the molecular ligand field or the interaction with the substrate as shown by YSR states observed on a related iron porphyrin molecule on Pb(111) substrate. 33 We have verified that the observed transitions result from inelastic spin excitations by acquiring the dI/dV spectra under an external magnetic field (B) perpendicular to the sample surface (see SI for details). The B-field dependence of the energies of the first and second feature is consistent with S = 1 with transverse anisotropy.…”
mentioning
confidence: 64%
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“…48 This ground state spin configuration can be altered by slight differences in the molecular ligand field or the interaction with the substrate as shown by YSR states observed on a related iron porphyrin molecule on Pb(111) substrate. 33 We have verified that the observed transitions result from inelastic spin excitations by acquiring the dI/dV spectra under an external magnetic field (B) perpendicular to the sample surface (see SI for details). The B-field dependence of the energies of the first and second feature is consistent with S = 1 with transverse anisotropy.…”
mentioning
confidence: 64%
“…3,7,12,[15][16][17][18][19][20][21][22][23][24][25][26][27][28][29] The bulk of recent experimental work on YSR states on superconducting (SC) substrates has demonstrated that the strength of the exchange interaction J can be significantly influenced by a small change in the adsorption site of the impurity or by spacers between the impurity and substrate. 3,18,[25][26][27][28][29][30][31][32][33][34] with α proportional to J, α = πρJS/2, where ρ is the normal-state density of states of the substrate at the Fermi level and S is the impurity spin. The bound state results from the spin-dependent scattering of Bogoliubov quasiparticles on the impurity and is thus associ-ated with the longitudinal part of the exchange interaction, JS z s z , where s represents the spin-density of the substrate electrons at the impurity position.…”
mentioning
confidence: 99%
“…In a classical picture, the energy position E YSR of the YSR state with respect to E F depends mainly on the s-d-or Kondo exchange coupling J K of the local spin of the atom to the substrate conduction electrons. 34 For low J K , the peaks merge with the coherence peaks at the gap edge ∆, whereas for higher J K , they shift towards E F and eventually cross it, commonly referred to as a quantum phase transition 37 . For even higher J K , the in-gap states merge with the coherence peaks again.…”
mentioning
confidence: 99%
“…Remarkably, with increasing magnetic field, the spatial extension of the Shiba state increases significantly further.Shiba states were widely studied in two different types of systems: a) in STM measurements, when magnetic particles are deposited on the surface of a superconductor [34][35][36][37][38][39][40][41][42][43][44][45], and b) in nanocircuits, when a quantum dot is attached to the superconductor . The STM geometry allows for the spatial mapping of the Shiba state [34][35][36][37], but the strength of the coupling between the magnetic adatom and the substrate is mostly determined by the microscopic details and its tuning remains quite challenging [40,43]. In contrast, the quantum dot realization enables the tuning the energy of the Shiba state via the level position or the tunnel couplings by using external gate voltages [58,59].…”
mentioning
confidence: 99%