Half-metallic finite zigzag single-walled carbon nanotubes from first principles

Mañanes, Á.; Duque, F.; Ayuela, Andrés; López, M. J.; Alonso, J. A.

doi:10.1103/physrevb.78.035432

Cited by 44 publications

(38 citation statements)

References 37 publications

(35 reference statements)

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“…We find that the magnetic moments are mainly located at the edges and decay exponentially when moving into the central part of the ribbon, in agreement with previous results. 10,39 Notice that the interlayer interaction between edges suppresses the site magnetization: for the planar cases, the magnetization value is about 0.25μ b . This is the case for all the magnetic configurations with AB β stacking and the AB α ones with FM intralayer coupling; see Fig.…”

Section: Structural and Magnetic Changes: Quenching Of The Edge Magnementioning

confidence: 99%

“…5(a). 10,39 It should be noted that the nanoribbon gaps may be underestimated in a GGA calculation. 40 The use of other functionals, such as the hybrid Heyd-Scuseria-Ernzerhof, 41 would correct this effect; in any case, the gap decrease with increasing width and the abrupt jumps associated with the magnetic changes will certainly hold in calculations employing other functionals, but with the quenching of magnetic moments taking place at larger widths.…”

Section: Implications Of the Magnetic Quenching For Calculations And mentioning

confidence: 99%

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van der Waals interaction in magnetic bilayer graphene nanoribbons

et al. 2012

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We study the interaction energy between two graphene nanoribbons by first-principles calculations, including van der Waals interactions and spin polarization. For ultranarrow zigzag nanoribbons, the direct stacking is even more stable than the Bernal stacking, competing in energy for wider ribbons. This behavior is due to the magnetic interaction between edge states. We relate the reduction of the magnetization in zigzag nanoribbons with increasing ribbon width to the structural changes produced by the magnetic interaction, and we show that when deposited on a substrate, zigzag bilayer ribbons remain magnetic for larger widths.

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Section: Structural and Magnetic Changes: Quenching Of The Edge Magnementioning

confidence: 99%

Section: Implications Of the Magnetic Quenching For Calculations And mentioning

confidence: 99%

van der Waals interaction in magnetic bilayer graphene nanoribbons

et al. 2012

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“…16 Our aim is to analyze the interplay between the singular magnetic properties of the finite ZNTs and the large magnetization of the encapsulated Fe clusters. As we have shown in a previous work, 15 the ZNTs present electronic properties associated to edge states similar to those of zigzag graphene ribbons, 17 therefore our study could be of relevance in analyzing the properties of proposed magnetoresistive devices based on zigzag graphene ribbons. 18 Furthermore, as far as finite ZNTs can be considered as organic molecules containing π electrons, our results can be useful in the interpretation of the local spin polarization at the organicferromagnetic interface, which has been recently described both theoretically and experimentally.…”

Section: Introductionmentioning

confidence: 63%

“…As for other finite ZNTs, 15 the ground state presents an AFM spin configuration along the tube, with zero total magnetic moment (μ T = 0). As an example, the spin structure of the ground state of the long (10,0) ZNT is given in Fig.…”

Section: B Finite Zigzag Carbon Nanotubesmentioning

confidence: 99%

“…The two ends show opposite orientation of the atomic magnetic moments. [12][13][14][15] Other states are close in energy to the ground state: magnetic states (M) with net total magnetic moment μ T different from zero (in some of these, the magnetic moments at the two edges show the same orientation [13][14][15], and a nonmagnetic (NM) state showing local spin compensation along the nanotube. The energy difference E(μ 0 T ) − E(AFM) between the lowest-lying magnetic state (with total magnetic moment μ 0 T ) and the ground state (AFM) decreases monotonically when the length of the nanotube increases, up to a point where the difference becomes lower than room temperature.…”

Section: Introductionmentioning

confidence: 99%

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Electronic and magnetic properties of Fe clusters inside finite zigzag single-wall carbon nanotubes

et al. 2013

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Density functional calculations of the electronic structure of the Fe 12 cluster encapsulated inside finite singlewall zigzag carbon nanotubes of indices (11,0) and (10,0) have been performed. Several Fe 12 isomers have been considered, including elongated shape isomers aimed to fit well inside the nanotubes, and the icosahedral minimum energy structure. We analyze the structural and magnetic properties of the combined systems, and how those properties change compared to the isolated systems. A strong ferromagnetic coupling between the Fe atoms occurs both for the free and the encapsulated Fe 12 clusters, but there is a small reduction (3-7.4 μ B ) of the spin magnetic moment of the encapsulated clusters with respect to that of the free ones (μ = 38 μ B ). The reduction of the magnetic moment is mostly due to the internal redistribution of the spin charges in the iron cluster. In contrast, the spin magnetic moment of the carbon nanotubes, which is zero for the empty tubes, becomes nonzero (1-3 μ B ) because of the interaction with the encapsulated cluster. We have also studied the encapsulation of atomic Fe and the growth of small Fe n clusters (n = 2, 4, 8) encapsulated in a short (10,0) tube. The results suggest that the growth of nanowires formed by distorted tetrahedral Fe 4 units will be favorable in (10,0) nanotubes and nanotubes of similar diameter.

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Half‐Metallic Carbon Nanotubes

Lee

2012

Advanced Materials

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Half-metallic finite zigzag single-walled carbon nanotubes from first principles

Cited by 44 publications

References 37 publications

van der Waals interaction in magnetic bilayer graphene nanoribbons

van der Waals interaction in magnetic bilayer graphene nanoribbons

Electronic and magnetic properties of Fe clusters inside finite zigzag single-wall carbon nanotubes

Half‐Metallic Carbon Nanotubes

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