Enhancement in the magnetic, optical and electrical properties of Ti0.97Co0.03O2and Ti0.97Fe0.03O2nanoparticles with Ce co-doping

Verma, Kuldeep Chand; Singh, Jaiveer; Ram, Mast; Sharma, D. P.; Sharma, Abhilasha; Kotnala, R.K.

doi:10.1088/0031-8949/86/02/025704

Cited by 16 publications

(3 citation statements)

References 31 publications

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“…The variations in M S values depend on factors like shape and size of nanostructures, concentration of dopants, and lattice defects. Furthermore, an F-center exchange (FCE) mechanism has been employed to illustrate the ferromagnetism of Fe-doped ZnO nanorods [51]. In this mechanism, the…”

Section: Temperature-dependent Magnetization In Gd/znomentioning

confidence: 99%

Diluted Magnetic Semiconductor ZnO: Magnetic Ordering with Transition Metal and Rare Earth Ions

Verma¹

2021

Magnetic Materials and Magnetic Levitation

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For advancement in future spintronics, the diluted magnetic semiconductors (DMSs) might be understood for their origin of ferromagnetic aptness. It not much clear to the ferromagnetism in DMS, that is intrinsic or via dopant clustering formation. For this, we have included a review study for the doping of transition metal and rare earth ions in ZnO. It is realized that the antiferromagnetic ordering is found in doped ZnO to achieve high-TC ferromagnetism. X-ray diffraction and Raman spectra techniques have been used to detect the wurtzite ZnO structure and lattice defects. Since ZnO has different types of morphology formation that is generally dependent on synthesis conditions and dopant level. The band gap energy of ZnO and lattice defect formation are shown by photoluminescence technique. The room temperature ferromagnetism is described with bound magnetic polaron (BMP) model in which oxygen vacancies play a major role. However, the temperature-dependent conditions are responsible for ferromagnetic ordering. The first principle calculation is used for dopant ions in ZnO for their replacement of Zn2+ atoms in the wurtzite structure as well as magnetic contribution.

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Section: Temperature-dependent Magnetization In Gd/znomentioning

confidence: 99%

Diluted Magnetic Semiconductor ZnO: Magnetic Ordering with Transition Metal and Rare Earth Ions

Verma¹

2021

Magnetic Materials and Magnetic Levitation

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“…The various essential properties like thermal, electrical conductivity, optical and magnetic can be enhanced by doping rare-earth ions with alkali metals [12]. Therefore, with the substitution of rare-earth, a modification in various physical properties has been achieved (optical, magnetic).…”

Section: Introductionmentioning

confidence: 99%

Effect of Annealing Temperature on Different Physical Properties of Sr0.5la0.5Mg0.5Fe11.5o19 Hexaferrite

Bhat¹,

Habib²,

Sharma³

et al. 2017

SAEA

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The influence of annealing on different physical properties of La0.5Mg0.5Sr0.5Fe11.5O19 hexaferrites prepared by the citrate-precursor method is presented in this study. The effects of temperature on the physical properties properties of the synthesized hexaferrites have been investigated using X-ray diffraction (XRD), Fourier transform infrared spectroscopy (FTIR), Scanning Electron Miscroscopy (SEM) and Vibrating Sample Magnetometer (VSM). The XRD study shows the formation of hexagonal structure with grain size lying between 23.86 nm and 56.12 nm. FTIR was used to study functional groups associated with the material. A decrease in saturation magnetization (Ms), and increase in Coercivity (HC) is observed with increase in temperature. Also, anisotropy constant was calculated by using Law of Approach to saturation and is well agreement with the literature.

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“…Simultaneously, the mechanism responsible for these states is controversial [13,14]. Recent studies have reported the sensitivity of the magnetism to the microstructure of the materials; various methods such as codoping and postannealing techniques are used to investigate the underlying mechanism [15][16][17][18][19]. In these studies, it is interesting to find that the structural defects in DMS seem to play important roles in mediating the magnetism.…”

Section: Introductionmentioning

confidence: 99%

Structure dependent photoluminescence and magnetic properties of Co:ZnS nanostructures

Chen¹,

Yang²,

Liu³

et al. 2013

Phys. Scr.

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Co:ZnS nanostructures have been synthesized via the solvothermal method by modifying the stoichiometry of Zn and S sources in the solvothermal process. The structure and morphology analysis demonstrates that the increase of the Zn/S molar ratio leads to changes in the morphology and structure, from Co:ZnS nanorods and hexagonal nanocrystals to core–shell Co:ZnS/ZnO nanocrystals. The photoluminescence spectrum for Co:ZnS/ZnO exhibits strong visible light emissions due to the presence of a large amount of structural defects, whereas the emissions for Co:ZnS nanorods almost disappear because of the high crystallinity. All the samples display obvious room-temperature ferromagnetism. The saturated magnetic moment of the samples strongly depends on the concentration of structural defects in the nanostructures and can be effectively enhanced by the introduction of abundant defects.

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Enhancement in the magnetic, optical and electrical properties of Ti_0.97Co_0.03O₂and Ti_0.97Fe_0.03O₂nanoparticles with Ce co-doping

Cited by 16 publications

References 31 publications

Diluted Magnetic Semiconductor ZnO: Magnetic Ordering with Transition Metal and Rare Earth Ions

Diluted Magnetic Semiconductor ZnO: Magnetic Ordering with Transition Metal and Rare Earth Ions

Effect of Annealing Temperature on Different Physical Properties of Sr0.5la0.5Mg0.5Fe11.5o19 Hexaferrite

Structure dependent photoluminescence and magnetic properties of Co:ZnS nanostructures

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