<i>In situ</i> synthesis of Mn-doped ZnO multileg nanostructures and Mn-related Raman vibration

Yang, Lili; Wu, Xiaoshan; Huang, G.S.; Qiu, Teng; Yu, Yang

doi:10.1063/1.1827917

Cited by 170 publications

(107 citation statements)

References 25 publications

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“…Good agreement with experimental spectrum was obtained using the following spin Hamiltonian parameters: = 2 00232, A = 80 G, D = 225 G and E = 10 G. In simulation, Gaussian-shaped lines with an internal peak-to-peak linewidth ∆B = 8 G were used. The calculated values of the spin Hamiltonian parameters agree reasonably well with the values reported in the literature for Mn 2+ doped ZnO single crystal [20]. It was also observed that the obtained values of the spin Hamiltonian parameters did not change much with temperature in the 4-300 K range, indicating on a rather weak contact with the surrounding lattice.…”

Section: Resultssupporting

confidence: 79%

Magnetic resonance study of nanocrystalline 0.10MnO/0.90ZnO

Żołnierkiewicz

Typek

Guskos³

et al. 2013

Open Physics

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Abstract:Magnetic properties of nanosize ZnO powders doped with MnO magnetic dopand have been studied. Sample designated as 0.10MnO/0.90ZnO was characterized by XRD that revealed the presence of ZnO and ZnMnO 3 phases. An average size of magnetic ZnMnO 3 nanocrystallites was 9 nm. Magnetic resonance study has been carried out in the 4-290 K temperature range. The spectrum at each temperature was analyzed in terms of three components. The temperature dependences of resonance field, linewidth and integrated intensity of these components have been determined. Magnetic centers responsible for producing the observed spectra have been proposed.

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Section: Resultssupporting

confidence: 79%

Magnetic resonance study of nanocrystalline 0.10MnO/0.90ZnO

Żołnierkiewicz

Typek

Guskos³

et al. 2013

Open Physics

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“…In addition to the normal modes of ZnO [5], the spectra of the Mn-doped ZnO crystals present two well-defined peaks at 523.3 cm -1 and 531 cm -1 which are obviously related to the manganese impurity. One of these two modes has already been observed near 522 cm -1 and attributed to the presence of Mn dopants in ZnO [6]. In fact, many other modes found in ZnO crystals doped with various impurities have already been reported in the literature [6][7][8][9].…”

Section: Raman Scattering Measurementsmentioning

confidence: 88%

“…One of these two modes has already been observed near 522 cm -1 and attributed to the presence of Mn dopants in ZnO [6]. In fact, many other modes found in ZnO crystals doped with various impurities have already been reported in the literature [6][7][8][9]. Some of these modes have since been identified to be normally silent B1 modes of wurtzite ZnO, activated by the breakdown of the translation crystal symmetry [10].…”

Section: Raman Scattering Measurementsmentioning

confidence: 90%

Raman scattering on Mn or Co doped ZnO crystals

Jouanne

Morhange

Szuszkiewicz

et al. 2006

Phys. Status Solidi (c)

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International audienceSingle crystals of bulk ZnO containing up to about 3% of Mn or Co were grown by chemical vapour transport method and characterized by Raman scattering. By comparison with Raman data taken on pure ZnO samples, a few new structures were observed in the spectra of the doped crystals. The determined frequencies of the new modes were compared with existing Raman data, corresponding to ZnO crystals containing various dopants, taken from the literature. A possible attribution of the observed modes to local impurity modes is discussed. (c) 2006 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim

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“…Moreover, layers codoped with two impurities (ZnO:Al:Mn) show essentially the same behavior, as far as the 530 cm -1 mode is concerned, and its relative importance increases with the Mn dose as can be seen in Fig 4c. Thus, we conclude that the extra mode is undoubtedly associated with Mn ions or atoms. As a matter of fact, such an extra mode has been observed before in ZnO:Mn doped films [4,13] and has been interpreted as a local mode due to Mn substituting Zn in a lattice site [14]. Although such an assignment seems reasonable, the effects of plasmon-phonon coupling, known to be important for GaAs:Mn [15], should be investigated by combining Raman and FIR spectroscopies.…”

Section: Contributedmentioning

confidence: 93%

Raman study of doped‐ZnO thin films grown by rf sputtering

Cerqueira

Rolo

Viseu

et al. 2010

Phys. Status Solidi (c)

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A Raman spectroscopy study of doped versus undoped ZnO layers is presented. The layers were grown by RF magnetron sputtering and the doping with Al, Sb and Mn was achieved by ion implantation with subsequent annealing. First‐order Raman response measured under λ=488 nm excitation is discussed. It is shown that doping with any of the impurities used in this work produces a strong enhancement of the longitudinal optical (LO) phonon band, which is attributed to the intra‐band Fröhlich mechanism. In addition, doping with Mn results in an extra mode located at 530 cm‐1, tentatively attributed to a local vibrational mode of Mn substituting Zn in the lattice sites. (© 2010 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)

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In situ synthesis of Mn-doped ZnO multileg nanostructures and Mn-related Raman vibration

Cited by 170 publications

References 25 publications

Magnetic resonance study of nanocrystalline 0.10MnO/0.90ZnO

Magnetic resonance study of nanocrystalline 0.10MnO/0.90ZnO

Raman scattering on Mn or Co doped ZnO crystals

Raman study of doped‐ZnO thin films grown by rf sputtering

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