Effect of magnetic fullerene on magnetization reversal created at the Fe/C60 interface

Mallik, Srijani; Mattauch, Stefan; Dalai, M. K.; Brückel, Thomas; Bedanta, Subhankar

doi:10.1038/s41598-018-23864-8

Cited by 28 publications

(48 citation statements)

References 50 publications

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“…This hard unit comprises the bottom FM layer that is coupled across the spinterface to a molecular spin chain through exchange bias. [ 15,30,40–45 ] In the spin chain's ground state, they represent one magnetic unit (thick green arrow in Figure 1d). However, in the experimental conditions of the data of Figure 1c, the AF spin chain is in the electrically excited state (Figure 1b) and can act as a distinct steady‐state magnetic unit (yellow/green arrow and box of Figure 1d).…”

Section: Resultsmentioning

confidence: 99%

“…It has a very low magnetic anisotropy and is exchange‐coupled with energy J 12 MSC to the bottom FM layer (Figure 1d). Due to exchange bias, [ 15,30,40–45 ] the excited spin chain can switch its magnetic orientation at H ≈ 1.1 T (yellow/green arrow in Figure 1c). The bottom magnetic unit, comprising the FM layer and spinterface, eventually switches at higher H (bottom green arrow in Figure 1c).…”

Section: Resultsmentioning

confidence: 99%

“…To conclude, although a standalone chain of paramagnetic centers has no intrinsic magnetic orientation and its quantum excited states are short‐lived, [ 14 ] these shortcomings can be overcome by coupling [ 15,41,42 ] it to a ferromagnetic layer. Using a novel resist‐and solvent‐free nanotechnological process, we demonstrated how this enables information to be encoded at magnetic remanence in the magnetic orientation of the spin chain's excited quantum state in a solid‐state device.…”

Section: Resultsmentioning

confidence: 99%

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Encoding Information on the Excited State of a Molecular Spin Chain

Katcko

Urbain

Ngassam

et al. 2021

Adv Funct Materials

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The quantum states of nano‐objects can drive electrical transport properties across lateral and local‐probe junctions. This raises the prospect, in a solid‐state device, of electrically encoding information at the quantum level using spin‐flip excitations between electron spins. However, this electronic state has no defined magnetic orientation and is short‐lived. Using a novel vertical nanojunction process, these limitations are overcome and this steady‐state capability is experimentally demonstrated in solid‐state spintronic devices. The excited quantum state of a spin chain formed by Co phthalocyanine molecules coupled to a ferromagnetic electrode constitutes a distinct magnetic unit endowed with a coercive field. This generates a specific steady‐state magnetoresistance trace that is tied to the spin‐flip conductance channel, and is opposite in sign to the ground state magnetoresistance term, as expected from spin excitation transition rules. The experimental 5.9 meV thermal energy barrier between the ground and excited spin states is confirmed by density functional theory, in line with macrospin phenomenological modeling of magnetotransport results. This low‐voltage control over a spin chain's quantum state and spintronic contribution lay a path for transmitting spin wave‐encoded information across molecular layers in devices. It should also stimulate quantum prospects for the antiferromagnetic spintronics and oxides electronics communities.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

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Encoding Information on the Excited State of a Molecular Spin Chain

Katcko

Urbain

Ngassam

et al. 2021

Adv Funct Materials

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“…We plotted the experimental data of reectivity vs. perpendicular scattering vector Q Z ¼ 4p sin q/l where Q Z is the component of momentum transfer perpendicular to the sample surface, thus, giving sample's layer-by-layer information. 19,20 We always applied positive saturation eld and then reverse the eld to the measurement elds. The guiding eld was À1 mT.…”

Section: Methodsmentioning

confidence: 99%

“…We measured two non-spin ipped scattering cross sections namely R ++ and R ÀÀ . 19,20 In R ++ , the rst + sign is for the incident neutron with up-spin polarization and the second + sign is for the reected neutron with up-spin polarization. Similarly, we can explain R ÀÀ (down-down).…”

Section: Methodsmentioning

confidence: 99%

Study of the magnetic interface and its effect in Fe/NiFe bilayers of alternating order

et al. 2020

Self Cite

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Self‐Assembled Fullerene Nanostructures: Synthesis and Applications

Baskar

Benzigar

Talapaneni

et al. 2021

Adv Funct Materials

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Functionalized fullerene nanostructures are a distinct class of materials that exhibit the combined properties of both fullerene and nanostructures including excellent optoelectronic features, modified band edges, high electron affinity, fast charge transfer capabilities, and tunable structural and textural properties. These fascinating properties allow for their utilization in many applications such as polymer solar cells, photovoltaics, photocatalysis, photodynamic therapy, electrocatalysis, environmental remediation, and drug and gene delivery. Numerous synthesis methods and anchoring groups are employed for functionalized fullerenes with nanostructures by using convergent bottom-up and top-down strategies. The supramolecular self-assembly and functionalization of fullerenes through robust chemistry approaches such as surface oxidation, grafting, polymer coating, doping of metals/nonmetal heteroatoms, noncovalent modification with 2D materials and nanoparticle attachment result in achieving fine control over its surface and bulk properties, including increased solubility, wettability, electron transport, acid-base properties, adsorption, electronic conductivity, and light absorption. This review analyzes the salient developments in the fabrication of nanostructured fullerenes and their functionalized derivatives for many applications including adsorption, catalysis, sensors, energy storage, solar cells, drug delivery, magnetic and superconducting devices. The contents of this review will allow the readers to cherish exciting possibilities and opportunities in field of functionalized nanofullerenes.

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Effect of magnetic fullerene on magnetization reversal created at the Fe/C60 interface

Cited by 28 publications

References 50 publications

Encoding Information on the Excited State of a Molecular Spin Chain

Encoding Information on the Excited State of a Molecular Spin Chain

Study of the magnetic interface and its effect in Fe/NiFe bilayers of alternating order

Self‐Assembled Fullerene Nanostructures: Synthesis and Applications

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