Ferromagnetism as a universal feature of nanoparticles of the otherwise nonmagnetic oxides

Sundaresan, A.; Bhargavi, R.; Rangarajan, N.; Siddesh, U.; Rao, C. N. R.

doi:10.1103/physrevb.74.161306

Cited by 1,342 publications

(839 citation statements)

References 24 publications

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“…Therefore, the magnitude of the saturation magnetization is in the order of 10 −1 emu/g, which is much larger than the moments of ZnObased dilute magnetic semiconductors doped with magnetic atoms 23 and is significantly larger than the measured moments originating from the broken bonds associated with the surface or atomic vacancies (typically in the order of less than 10 −3 emu/g) in pure ZnO measured using nanoparticles 24,25 or nanograined thin films. 26 However, it is quite comparable to the calculated M S of 0.069−0.34 emu/g obtained based on our first principles calculation discussed earlier, assuming the magnetic moment of 0.001−0.005 μ B /atom depending on the thickness of the nanoplates as in Table 1.…”

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confidence: 75%

Magnetism in Dopant-Free ZnO Nanoplates

et al. 2012

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It is known that bulk ZnO is a nonmagnetic material. However, the electronic band structure of ZnO is severely distorted when the ZnO is in the shape of a very thin plate with its dimension along the c-axis reduced to a few nanometers while keeping the bulk scale sizes in the other two dimensions. We found that the chemically synthesized ZnO nanoplates exhibit magnetism even at room temperature. First-principles calculations show a growing asymmetry in the spin distribution within the distorted bands formed from Zn (3d) and O (2p) orbitals with the reduction of thickness of the ZnO nanoplates, which is suggested to be responsible for the observed magnetism. In contrast, reducing the dimension along the a-or b-axes of a ZnO crystal does not yield any magnetism for ZnO nanowires that grow along c-axis, suggesting that the internal electric field produced by the large {0001} polar surfaces of the nanoplates may be responsible for the distorted electronic band structures of thin ZnO nanoplates.

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confidence: 75%

Magnetism in Dopant-Free ZnO Nanoplates

et al. 2012

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“…Recently, in Ref. 67, surface-vacancy-induced ferromagnetism was obtained for a series of oxide materials including ZnO. In the present situation also, defects may play important roles in obtaining ferromagnetism.…”

Section: Discussion About the Presence Of Fe 3+mentioning

confidence: 99%

“…This can happen mostly on the surface of the nanoparticles, where the probability of the presence of vacancies is higher. 67 The increase in the intensity of the EPR signal B with lowering of the temperature may be due to freezing of these Fe 3+ spins. This observation is consistent with the increase in the paramagnetic contribution as seen in the low-temperature hysteresis loops.…”

Section: Discussion About the Presence Of Fe 3+mentioning

confidence: 99%

Ferromagnetism in Fe-doped ZnO nanocrystals: Experiment and theory

et al. 2007

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Fe-doped ZnO nanocrystals are successfully synthesized and structurally characterized by using x-ray diffraction and transmission electron microscopy. Magnetization measurements on the same system reveal a ferromagnetic to paramagnetic transition temperature above 450 K with a low-temperature transition from the ferromagnetic to the spin-glass state due to canting of the disordered surface spins in the nanoparticle system. Local magnetic probes like electron paramagnetic resonance and Mössbauer spectroscopy indicate the presence of Fe in both valence states Fe 2+ and Fe 3+ . We argue that the presence of Fe 3+ is due to possible hole doping in the system by cation ͑Zn͒ vacancies. In a subsequent ab initio electronic structure calculation, the effects of defects ͑e.g., O and Zn vacancies͒ on the nature and origin of ferromagnetism are investigated for the Fe-doped ZnO system. Electronic structure calculations suggest hole doping ͑Zn vacancy͒ to be more effective to stabilize ferromagnetism in Fe-doped ZnO and our results are consistent with the experimental signature of hole doping in ferromagnetic Fe-doped ZnO samples.

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“…Dilute ferromagnetism in oxide semiconductors generally has been reported with 3d dopants in ZnO particularly with Mn, Co, Ni, Fe, Cu, and V dopings. [1][2][3] Unexpected magnetization without transition metal has been reported in dielectric oxides such as HfO 2 , ZrO 2 , 4 and nonmagnetic oxides, e.g., ZnO, 5 hexaborides, 6 carbon-doped ZnO, 7 and in irradiated graphite. 8 The theory of Dietl et al 9 suggests that carrier-induced ferromagnetism in Mn-doped p-type material may be observed at higher temperature.…”

Section: Introductionmentioning

confidence: 99%

Room-temperature ferromagnetism in Li-dopedp-type luminescent ZnO nanorods

2009

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We have observed ferromagnetism in Li-doped ZnO nanorods with Curie temperature up to 554 K. Li forms shallow acceptor states in substitutional zinc sites giving rise to p-type conductivity. An explicit correlation emerges between increase in hole concentration with decrease in magnetization and Curie temperature in ZnO:Li. Occurrence of ferromagnetism at room temperature has been established with observed magnetic domain formation in ZnO:Li pellets in magnetic force microscopy and prominent ferromagnetic resonance signal in electron paramagnetic resonance spectrum. Magnetic ZnO:Li nanorods are luminescent, showing strong near UV emission. Substitutional Li atoms can induce local moments on neighboring oxygen atoms, which when considered in a correlated model for oxygen orbitals with random potentials introduced by dopant atom could explain the observed ferromagnetism and high Curie temperature in ZnO:Li nanorods.

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Ferromagnetism as a universal feature of nanoparticles of the otherwise nonmagnetic oxides

Cited by 1,342 publications

References 24 publications

Magnetism in Dopant-Free ZnO Nanoplates

Magnetism in Dopant-Free ZnO Nanoplates

Ferromagnetism in Fe-doped ZnO nanocrystals: Experiment and theory

Room-temperature ferromagnetism in Li-dopedp-type luminescent ZnO nanorods

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