Electron-vibron coupling effects on electron transport via a single-molecule magnet

McCaskey, Alexander; Yamamoto, Yoh; Warnock, Michael; Burzurí, Enrique; Zant, Herre S. J. van der; Park, K.

doi:10.1103/physrevb.91.125419

Cited by 16 publications

(15 citation statements)

References 60 publications

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“…In particular, in magnetic molecules the interplay of vibrational modes, or vibrons, with the spin degrees of freedom is known to impact the spin lifetime [4][5][6]. Since vibrational modes can couple to the electric charge, producing vibron-assisted electron excitations in transport [7][8][9], expectations are that similar effects should be also observed with the electronic spin [10,11].Concerning this last point, experimental work has predominantly focused on a well-known spin-related manybody effect, the Kondo effect. The electron-vibron interaction in Kondo molecules was shown to produce satellite Kondo resonances in the differential conductance spectra at the bias of the vibron's excitation energy [12][13][14].…”

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confidence: 99%

Vibron-assisted spin excitation in a magnetically anisotropic molecule

et al. 2020

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The ability to electrically-drive spin excitations in molecules with magnetic anisotropy is key for high-density storage and quantum-information technology. Electrons, however, also tunnel via the vibrational excitations unique to a molecule. The interplay of spin and vibrational excitations offers novel routes to study and, ultimately, electrically manipulate molecular magnetism. Here we use a scanning tunneling microscope to electrically induce spin and vibrational excitations in a single molecule consisting of a nickelocene magnetically coupled to a Ni atom. We evidence a vibron-assisted spin excitation at an energy one order of magnitude higher compared to the usual spin excitations of nickelocene and explain it using first-principles calculations that include electron correlations. Furthermore, we observe that spin excitations can be quenched by modifying the Ni-nickelocene coupling. Our study suggests that nickelocene-based complexes constitute a model playground for exploring the interaction of spin and vibrations in the electron transport through single magnetic molecules.Magnetic molecules are potential candidates for information-storing technology [1], molecular spintronics [2] and quantum computing [3], provided that their axial magnetic anisotropy DS 2 z ensures a magnetic bistability among longlived magnetic states. But molecules also vibrate. In particular, in magnetic molecules the interplay of vibrational modes, or vibrons, with the spin degrees of freedom is known to impact the spin lifetime [4][5][6]. Since vibrational modes can couple to the electric charge, producing vibron-assisted electron excitations in transport [7][8][9], expectations are that similar effects should be also observed with the electronic spin [10,11].Concerning this last point, experimental work has predominantly focused on a well-known spin-related manybody effect, the Kondo effect. The electron-vibron interaction in Kondo molecules was shown to produce satellite Kondo resonances in the differential conductance spectra at the bias of the vibron's excitation energy [12][13][14]. These resonances were ascribed to tunneling electrons that have their spin flipped when elastically scattering off the molecular spin, but with sufficient energy to activate a vibrational mode in the molecule [15]. The question arises whether a similar mechanism is also possible with other spin scattering mechanisms that magnetically excite a molecule such as inelastic scattering involving magnetic anisotropy [16]. These so-called spin excitations show great potential in view of an all-electrical manipulation of the molecular spin [17,18].Here, we use scanning tunneling microscopy (STM) to demonstrate the presence of a combined vibrational-spin excitation in a single nickelocene molecule [Ni(C 5 H 5 ) 2 , see Fig. 1(d); noted Nc hereafter] coupled to a Ni atom. Nickelocene is a spin S = 1 molecule of the metallocene family with magnetic anisotropy, where spin excitations produce a sizable increase of the electronic transport [19]. We show that the o...

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confidence: 99%

Vibron-assisted spin excitation in a magnetically anisotropic molecule

et al. 2020

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“…A large number of extensions to this model has been developed to take into account specific details of transport spectra, see, e.g., Refs. [8,19,[27][28][29][30][31][32][33][34][35][36][37][38][39][40][41][42]; however, for now we focus our analysis on the simplest theoretical case, assuming a single harmonic oscillator mode and fast relaxation into the vibrational ground state. In this case, the current step heights or conductance peak amplitudes follow the Poisson formula [4,10], P n = (e −g g n )/n!, n = 0, 1, 2, .…”

Section: Franck-condon Modelmentioning

confidence: 99%

Magnetic field control of the Franck-Condon coupling of few-electron quantum states

et al. 2020

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Suspended carbon nanotubes display at cryogenic temperatures a distinct interaction between the quantized longitudinal vibration of the macromolecule and its embedded quantum dot, visible via Franck-Condon conductance sidebands in transport spectroscopy. We present data on such sidebands at known absolute number N el = 1 and N el = 2 of conduction band electrons and, consequently, well-defined electronic ground and excited states in a clean nanotube device. The interaction evolves only at a finite axial magnetic field and displays a distinct magnetic-field dependence of the Franck-Condon coupling parameter, different for different electronic base states and indicating a valley dependence. Reshaping of the electronic wave function by the magnetic field is discussed as a possible cause of our observations; its impact is demonstrated in a model calculation reproducing the field-dependent coupling.

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“…As the calculations are restricted to molecular systems, they were performed on the isolated Fe 4 complexes using the experimental structures. [46][47][48] For the deposited systems, the molecular structure was taken from the structural optimization with the gold surface, but the zero-field splitting parameters were determined for the molecule alone, without the surface.…”

Section: Computational Detailsmentioning

confidence: 99%

“…Magnetic anisotropy controlled the electric field as proposed by Zyazin et al 18,33,48 is based on the change of the oxidation state of the ICOCIN Fe 4 complex from the S=5 neutral state to a reduced S=11/2 state with a change in the D parameter from -0.06 to -0.09 meV (-0.48 to -0.27 cm -1 ). We performed DFT calculations using the Gaussian code with the B3LYP functional (see Computational details) to compare the energies of the optimized neutral, reduced and oxidized NIPJEC Fe 4 complex.…”

Section: Zero-field Splitting Parameters Of Isolated Fe 4 Complexes Amentioning

confidence: 99%

Magnetic and transport properties of Fe₄single-molecule magnets: a theoretical insight

2016

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Here, methods of density functional theory (DFT) were employed to study the magnetic and transport properties of a star-shaped single-molecule magnet FeS = 5 complex deposited on a gold surface. The study devoted to the magnetic properties focused on changes in the exchange coupling constants and magnetic anisotropy (zero-field splitting parameters) of the isolated and deposited molecules. Molecule-surface interactions induced significant changes in the antiferromagnetic exchange coupling constants because these depend closely on the geometry of the metal complex. Meanwhile, the magnetic anisotropy remained almost constant. Transport properties were analysed using two different approaches. First, we studied the change in magnetic anisotropy by reducing and oxidizing the Fe complex as in a Coulomb blockade mechanism. Then we studied the coherent tunnelling using DFT methods combined with Green functions. Spin filter behaviour was found because of the different numbers of alpha and beta electrons, due to the S = 5 ground state.

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Electron-vibron coupling effects on electron transport via a single-molecule magnet

Cited by 16 publications

References 60 publications

Vibron-assisted spin excitation in a magnetically anisotropic molecule

Vibron-assisted spin excitation in a magnetically anisotropic molecule

Magnetic field control of the Franck-Condon coupling of few-electron quantum states

Magnetic and transport properties of Fe₄single-molecule magnets: a theoretical insight

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Electron-vibron coupling effects on electron transport via a single-molecule magnet

Cited by 16 publications

References 60 publications

Vibron-assisted spin excitation in a magnetically anisotropic molecule

Vibron-assisted spin excitation in a magnetically anisotropic molecule

Magnetic field control of the Franck-Condon coupling of few-electron quantum states

Magnetic and transport properties of Fe4single-molecule magnets: a theoretical insight

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Magnetic and transport properties of Fe₄single-molecule magnets: a theoretical insight