Your search keyword '"Manzoor, Alina"' showing total 9 results

1. Transport Properties of Ce-Doped Cd Ferrites CdFe2−xCexO4

Author

Amin, Nasir, Razaq, Abdul, Rehman, Atta Ur, Hussain, Khalid, Nabi, M. Ajaz Un, Morley, N. A., Amami, Mongi, Bibi, Aisha, Arshad, Muhammad Imran, Mahmood, Khalid, Fatima, Muneeba, Akhtar, Maria, Akbar, Sofia, Manzoor, Alina, Ali, Hafiz T., Yusuf, Mohammad, and Amin, Sana

Published

2021

2. Dielectric, XPS, and ferromagnetic relaxation studies of Ho-substituted polycrystalline magnetic oxide materials.

Author

Manzoor, Alina, Azhar Khan, Muhammad, Afzal, Amir Muhammad, Arshad, Muhammad Imran, Shahzad, Aamir, Akbar, Sofia, Kashif, Muhammad, Ashraf, Ghulam Abbas, Khan, Muhammad Yaqoob, Rasul, M. Nasir, Shifa, Muhammad Shahzad, Nasar, Gulfam, and Hussain, Altaf

Subjects

*MAGNETIC materials, *HOLMIUM, *X-ray photoelectron spectroscopy, *THERMOELECTRIC power, *FERROMAGNETIC resonance, *DIELECTRICS, *MANGANITE, *SPINEL group

Abstract

The impact of holmium (Ho) ions on lithium-rich spinel ferrites is studied through magnetic, morphological, and electrical transport properties. The X-ray photoelectron spectroscopy (XPS) analysis indicated the existence of all metal ions in the required valence state. Transmission electron microscopy (TEM) analysis exhibited nano-crystalline (∼50 nm) structures of these ferrites. The electrical resistivity measurements showed the higher resistivity values of the synthesized samples. The resistivity increased from 2.4 × 108 to 2.1 × 1010 Ω-cm with Ho inclusion, indicated an inverse relation with the size of grains. The Curie temperature (T c ) observed to decrease from 848 to 806 K with the incorporation of Ho 3+ ions. The activation energy (Δ E a ) noted to vary between 0.21 and 0.23 eV. The drift mobility (μ d) study revealed a decrease from 1.86x10 −12 to 6.14x10 −14 cm 2 V −1 s −1 by increasing Ho amount up to x = 0.06. A reduction in thermoelectric power (S) from - 143 to -95 μ.V/K by increase in Ho concentration confirmed the Fe replacement by Ho on octahedral B-sites. The ferromagnetic resonance (FMR) investigations indicated a drop in FMR line-broadening (ΔH) from 2491 to 2000 Oe by the increase of Ho concentration, making it beneficial to reduce microwave losses. A non-linear variation in the resonance field (H res) with the substitution of Ho was observed between 7359 to 7785 Oe. [ABSTRACT FROM AUTHOR]

Published

2022

3. Effects of size and oxygen annealing on the multiferroic behavior of bismuth ferrite nanoparticles

Author

Manzoor, Alina, Hasanain, S. K., Mumtaz, A., Bertino, M. F., and Franzel, L.

Published

2012

4. Transport Properties of Ce-Doped Cd Ferrites CdFe2−xCexO4.

Author

Amin, Nasir, Razaq, Abdul, Rehman, Atta Ur, Hussain, Khalid, Nabi, M. Ajaz Un, Morley, N. A., Amami, Mongi, Bibi, Aisha, Arshad, Muhammad Imran, Mahmood, Khalid, Fatima, Muneeba, Akhtar, Maria, Akbar, Sofia, Manzoor, Alina, Ali, Hafiz T., Yusuf, Mohammad, and Amin, Sana

Subjects

FERRITES, NICKEL ferrite, CERIUM oxides, METALLIC oxides, LATTICE constants, UNIT cell, CELL size

Abstract

Cadmium ferrites belong to normal spinel ferrites, and they exhibit interesting electrical, magnetic, and optical properties. The pure and cerium-doped cadmium ferrites CdFe2−xCexO4 (x = 0.0, 0.125, 0.250, 0.375, 0.5) were synthesized by a chemical co-precipitating technique using sodium hydroxide as a co-precipitating agent. The structures and phase purity of fabricated nanomaterials were analyzed by X-ray diffraction (XRD). The crystallite size for all the prepared nanomaterials was in the range of 28–46 nm. The lattice constant and unit cell volume were found to decrease with the increasing concentration of Cerium, which was confirmed by the peak shift in the XRD pattern. The X-ray density for all nano ferrites increased with the enhancement of cerium composition. The resistivity of the nanomaterials has random behavior with the enhancement of cerium composition for a temperature, but the value of resistivity at x = 0.125 has the lowest value and at x = 0.375 has the highest value for almost all temperatures. For specific concentrations, a decreasing trend of resistivity of fabricated materials was found with an increment of temperature. The activation energies were also calculated, and it increased for x = 0.125 and then decreased for all the nanomaterials. For the confirmation of the M–O bonds, FTIR analysis of all the nano ferrites was also performed. The analysis shows a higher frequency absorption band in the range of 531.24–534.84 cm−1. This absorption band confirms that metal oxides are formed in all the synthesized nanoparticles. [ABSTRACT FROM AUTHOR]

Published

2021

5. Effect of Ho3+ ions on microwave losses and high-temperature electrical behavior of Li-based magnetic oxides.

Author

Manzoor, Alina, Khan, Muhammad Azhar, Alshahrani, Thamraa, Alhossainy, M.H., Sharif, M., Munir, Tariq, Arshad, Muhammad Imran, and Iqbal, M. Asif

Subjects

*HOLMIUM, *MICROWAVES, *PARTICLE size distribution, *X-ray photoelectron spectroscopy, *FERROMAGNETIC resonance, *TRANSMISSION electron microscopy

Abstract

We investigate here the effect of holmium on Li–Co nano-ferrites to elaborate the surface morphology, dynamic magnetic and electrical transport properties. The transmission electron microscopy (TEM) technique was employed to examine the microstructure and grain size distribution. TEM analysis confirmed the nanocrystalline nature (~50 nm) of the prepared materials. X-ray photoelectron spectroscopy (XPS) experiment results verify the presence of all metal ions with the required valences. Ferromagnetic resonance (FMR) analysis revealed the need for a dense microstructure to cut down the microwave losses. FMR line width was observed to reduce from 2757 -to 1676 Oe except for x = 0.12 by the substitution of Ho ions which correspond to low microwave losses. The dc resistivity results show that high resistivity values are associated with smaller grains of the samples and vice versa. Resistivity values are found to increase from 3.66 × 108 -to 5.31 × 108 Ω-cm by increasing the Ho addition. Seebeck experiment revealed n-type conduction. Together with showing the nature of charge carriers, a decrease in the Seebeck coefficient with increasing Ho ensured the replacement of Fe ions by Ho ions on B-sites. [ABSTRACT FROM AUTHOR]

Published

2021

6. Microstructure, ferromagnetic resonance, and electrical analysis of Ho-substituted Li-Ni nanoparticles.

Author

Manzoor, Alina, Shahzad, Aamir, Kuch, Wolfgang, Shinwari, Tauqir, Kumberg, Ivar, Shokr, Yasser A., and Khan, Muhammad Azhar

Subjects

*FERROMAGNETIC resonance, *HOLMIUM, *RARE earth ions, *X-ray photoelectron spectroscopy, *MAGNETIC nanoparticles, *MAGNETIC properties

Abstract

The substitution of rare earth ions is a novel approach to vary the dynamic magnetic properties of soft ferrites to such an extent that its electrical properties and ferromagnetic resonance (FMR) response can be set over a broad frequency range. In this work, a complete transmission electron microscopy (TEM), scanning electron microscopy (SEM), ferromagnetic resonance spectroscopy (FMR), X-ray photoelectron spectroscopy (XPS), and current-voltage (I-V) analysis of holmium (Ho) substituted lithium-nickel soft ferrites with composition Li 1.2 Ni 0.4 Fe 2−x Ho x O 4 (x = 0, 0.03, 0.06, 0.09, 0.12, and 0.15) is carried out. TEM analysis reveals a spherical shape distribution of nanoparticles with a particle size of ∼ 50 nm. FMR study is carried out to check the role of Ho addition on magnetic energy losses, FMR line position, and shape. The shift in FMR line shape is mainly attributed to the anisotropy contribution, relaxation processes, and ferromagnetic interactions between the magnetic nanoparticles. XPS experiments confirm the presence of all compositional elements along their valence states. The Ho substitution increased the electrical resistivity, whereas the damping of A-B exchange interactions resulted in a decline of Curie temperature (T c), which is required for high-frequency power applications. • TEM study of Ho-doped Li-Ni ferrites revealed an average particle size of ∼ 50 nm. • XPS experiments confirm the presence of all compositional elements along their valence states. • Enhanced electrical resistivity and a decline in Curie temperature as a function of Ho were observed. • FMR losses were reduced by replacing the Fe ions with Ho ions required for high-frequency power applications. [ABSTRACT FROM AUTHOR]

Published

2023

7. Transport Properties of Ce-Doped Cd Ferrites CdFe2−xCexO4.

Author

Amin, Nasir, Razaq, Abdul, Rehman, Atta Ur, Hussain, Khalid, Nabi, M. Ajaz Un, Morley, N. A., Amami, Mongi, Bibi, Aisha, Arshad, Muhammad Imran, Mahmood, Khalid, Fatima, Muneeba, Akhtar, Maria, Akbar, Sofia, Manzoor, Alina, Ali, Hafiz T., Yusuf, Mohammad, and Amin, Sana

Subjects

*FERRITES, *NICKEL ferrite, *CERIUM oxides, *METALLIC oxides, *LATTICE constants, *UNIT cell, *CELL size

Abstract

Cadmium ferrites belong to normal spinel ferrites, and they exhibit interesting electrical, magnetic, and optical properties. The pure and cerium-doped cadmium ferrites CdFe2−xCexO4 (x = 0.0, 0.125, 0.250, 0.375, 0.5) were synthesized by a chemical co-precipitating technique using sodium hydroxide as a co-precipitating agent. The structures and phase purity of fabricated nanomaterials were analyzed by X-ray diffraction (XRD). The crystallite size for all the prepared nanomaterials was in the range of 28–46 nm. The lattice constant and unit cell volume were found to decrease with the increasing concentration of Cerium, which was confirmed by the peak shift in the XRD pattern. The X-ray density for all nano ferrites increased with the enhancement of cerium composition. The resistivity of the nanomaterials has random behavior with the enhancement of cerium composition for a temperature, but the value of resistivity at x = 0.125 has the lowest value and at x = 0.375 has the highest value for almost all temperatures. For specific concentrations, a decreasing trend of resistivity of fabricated materials was found with an increment of temperature. The activation energies were also calculated, and it increased for x = 0.125 and then decreased for all the nanomaterials. For the confirmation of the M–O bonds, FTIR analysis of all the nano ferrites was also performed. The analysis shows a higher frequency absorption band in the range of 531.24–534.84 cm−1. This absorption band confirms that metal oxides are formed in all the synthesized nanoparticles. [ABSTRACT FROM AUTHOR]

Published

2021

8. Structural and electromagnetic characterization of Co-Mn doped Ni-Sn ferrites fabricated via micro-emulsion route.

Author

Ali, Rajjab, Shahid, Muhammad, FarooqWarsi, Muhammad, Azhar Khan, Muhammad, and Manzoor, Alina

Subjects

*FERRITES synthesis, *MAGNETIC properties, *DIELECTRIC properties, *X-ray diffraction, *CRYSTAL structure

Abstract

Ni 0.5 Sn 0.5 Co x Mn x Fe 2−2x O 4 ferrites with x = 0.0–0.8 have been prepared by the micro-emulsion method, using CTAB as a surfactant material. X-ray diffraction (XRD), Fourier transformed infrared spectroscopy (FTIR) and vibrational sample magnetometer (VSM) were used to investigate the effects of Co and Mn substitutions on cationic distribution, crystallite size, lattice constant, spectral, magnetic and dielectric properties. Lattice constant and crystallite size were found to increase from 7.4 to 9.25 Å and from 11.8 to 19.7 nm respectively with increasing substitution of Co and Mn ions. Saturation magnetization (M S ) gradually increased from 20.5 to 47.6 emu/g with increase in the value of x. However, Coercivity increased from 152.7 to 462.4 Oe up to x = 0.4 and then it decreased thereafter. The dielectric constant, complex dielectric constant and tan loss (tanδ) were observed to decrease with increase in frequency, depicting the semiconductor behavior of the ferrites. Dc resistivity was observed to decrease considerably upon addition of Co and Mn content. The outcome for the tunable magnetic properties and achieved modification of the synthesized nanocrystallites may be chosen for tremendous applications; such as miniaturized memory devices that are based on the energy storage principles and capacitive components. [ABSTRACT FROM AUTHOR]

Published

2017

9. Structural, optical, electrical and thermo-electrical properties of Cu doped Co9S8-NPs synthesized via co-precipitation method.

Author

Munir, Tariq, ur Rehman, Naeem, Mahmood, Arslan, Mahmood, Khalid, Ali, Adnan, Khan, Imran, Sohail, Amjad, and Manzoor, Alina

Subjects

*COPRECIPITATION (Chemistry), *THERMOELECTRIC materials, *BAND gaps, *COBALT sulfide, *CRITICAL temperature

Abstract

• Copper doped cobalt sulphide nanoparticles were synthesized co-precipitation method. • Cubic structure of Cu doped Co 9 S 8 -NPs was observed at most prominent peak. • The red shift appeared in Cu doped Co 9 S 8 -NPs most suitable for photo-catalytic activity. • Electrical result shows that conductivity increases and resistivity decreases. • Thermoelectric measurements at unique critical temperature to rising current exponentially. Pure and copper doped cobalt sulphide (Co 9 S 8) nanoparticles were synthesized using aqueous chemical co-precipitation method. To study the effect of elemental composition Cu (0%, 1%, 5%, 10% &15%) on structural, optical, electrical and thermoelectric properties of Co 9 S 8 nanoparticles were investigated using various characterization techniques such as XRD, SEM, FTIR, UV–VIS and two probe methods. Cubic structure and grain size of pure and Cu doped Co 9 S 8 -NPs was confirmed by X-ray diffraction and SEM analysis. FTIR spectrum showed the different rotational and vibrational mode attached on the surface of the material. A redshift appeared in the band gap value (E g) as a function of the Cu dopant and high absorbance in the optical region makes the material suitable for photocatalytic activity. The electrical result show that conductivity increases and resistivity decreased as Cu content increases in Co 9 S 8 -NPs. Finally, thermoelectric measurements referred to the unique critical temperature for each sample where current starts rising exponentially. [ABSTRACT FROM AUTHOR]

Published

2020