Your search keyword '"Sahoo M"' showing total 6 results

1. Display of converse and direct magnetoelectric effect in double perovskite LaYFe2O6.

Author

Ghosh, R., Barik, A., Sahoo, M. R., Tiwary, Sweta, Babu, P. D., Kaushik, S. D., and Vishwakarma, P. N.

Subjects

MAGNETOELECTRIC effect, TRANSITION temperature, MAGNETIC transitions, PEROVSKITE, NEUTRON diffraction, MAGNETIC entropy

Abstract

This work reports the simultaneous observation of converse magnetoelectric (CME) and direct magnetoelectric (DME) effects in LaYFe2O6. The structural, magnetic, and magnetoelectric properties of LaYFe2O6, prepared by the sol-gel auto-combustion method and sintered at various temperatures, have been studied. The x-ray powder diffraction study suggests the double perovskite structure with symmetries P21nm (∼90%) and Pbnm (∼10%). The alternate ordering of La and Y ions is confirmed by the neutron powder diffraction (ND) study, which also suggests the antiferromagnetic (AFM) ordering of spins. AFM behavior is also manifested by the magnetic field-dependent magnetization (M) measurement. A higher P21nm phase content is desirable in the context of magnetoelectricity. Magnetic transition (∼700 K) is asserted in the temperature-dependent M measurement. The isothermal magnetization study shows weak ferromagnetism probably due to gradually increasing spin canting with temperature until the transition temperature. The highest CME coefficient (∼2.26 mOe cm/V) as well as DME coefficient (∼0.45 mV/cm Oe) in this material are recorded. True magnetoelectricity for temperature as high as 400 K opens up a new avenue on the playground of magnetoelectric (ME)-based applications. [ABSTRACT FROM AUTHOR]

Published

2022

2. Tuning the Magnetic and Electrical Properties of LaYFe2O6 by Mn Substitution.

Author

Ghosh, R., Barik, A., Sahoo, M. R., Mishra, S., and Vishwakarma, P. N.

Subjects

MAGNETIC properties, MAGNETIC transitions, X-ray photoelectron spectroscopy, TRANSITION temperature, MAGNETIC fields

Abstract

Herein, we report a fundamental study revealing the substantial change in magnetic and electrical properties promoted by manganese (Mn) substitution in the iron (Fe) site of double perovskite LaYFe2O6 [LaYFe2-xMnxO6; x = 0, 0.05, 0.10, and 0.15], which is prepared by the sol–gel auto-combustion method. The structural, morphological, magnetic, and electrical properties of all the samples are investigated to explore the influence of Mn in the compound. X-ray diffraction (XRD) study reveals the confirmation of phase formation with orthorhombic crystal structure having symmetries P21nm and Pbnm (small contribution). X-ray photoelectron spectroscopy (XPS) analysis corroborates the mixed valence state of Fe and Mn, while the dominancy of + 3 oxidation state can be confirmed for them. Magnetization study reveals that the transition temperature reduces drastically (~ 100 K) by the Mn substitution and approaches toward room temperature (RT). At 573 K, the maximum magnetization value enhanced up to ~ 30% by the Mn substitution. Grain boundary contribution in the electrical response is more prominent in the higher Mn content samples. The application of DC magnetic field exhibits a significant influence on the impedance spectra due to the substitution of Mn in the lattice, which corroborates the signature of magnetoelectric (ME) coupling. The presence of ME coupling is further confirmed by the direct magnetoelectric measurement. This finding along with the above RT magnetic transition could make it a feasible candidate for ME-based applications. [ABSTRACT FROM AUTHOR]

Published

2024

3. Effect of crystal symmetries and phase boundaries on the magnetoelectricity of La2NiMnO6 prepared under ambient conditions.

Author

Tiwary, Sweta, Kuila, S., Sahoo, M. R., Barik, A., Ghosh, R., Krishna, P. S. R., Babu, P. D., Siruguri, V., Choudhary, R. J., Sinha, A. K., and Vishwakarma, P. N.

Subjects

CRYSTAL symmetry, SYNCHROTRONS, TRANSITION temperature, X-ray powder diffraction, HOPPING conduction, NEUTRON diffraction, MAGNETIC transitions, NEUTRON sources

Abstract

La2NiMnO6 prepared under ambient conditions are analyzed for their crystal phase symmetry via powder x-ray diffraction in the laboratory as well as synchrotron sources and neutron powder diffraction. The room temperature symmetry is found to be R − 3 c for samples having a sintering temperature less than 800 °C and gradually increasing participation of P 2 1 / n symmetry is observed for higher sintering temperature samples. A crystallographic phase transition at ∼650 K from biphasic (R − 3 c + P 2 1 / n) to monophasic (R − 3) for all samples is observed. This transition is found to be endowed with a small amount of magnetic ordering at the transition temperature. The measured magnetoelectricity on these samples displayed their direct dependence on relative crystal phase symmetries, such that magnetoelectricity is highest for the equifraction content of R − 3 c and P 2 1 / n symmetries. The temperature variation of the first order magnetoelectric coefficient is observed to be proportional to T − 0.25 , which is analogous to the Mott variable range hopping conduction exhibited by these compounds. Corroboration of observed results suggests the interfacial origin of magnetoelectricity in these samples. [ABSTRACT FROM AUTHOR]

Published

2020

4. Evolution of structural and magnetic property of Mn doped barium hexaferrite.

Author

Sahoo, M. R., Barik, A., Tiwary, Sweta, Ghosh, R., Vishwakarma, P. N., Sharma, Veerendra K., Prajapat, C. L., and Yusuf, S. M.

Subjects

*MAGNETIC properties, *BARIUM, *TRANSITION temperature, *LATTICE constants, *SOL-gel processes, *CHEMICAL-looping combustion

Abstract

The Manganese (Mn) doped barium hexaferrite (BaFe12-xMnxO19) is synthesized by the sol-gel auto-combustion method. The structural and magnetic properties are studied for x = 0, 3, 7 and 9 compounds. The lattice parameter 'a=b' increases and 'c' decreases with the increase in Mn fraction. The saturation magnetization shows a drastic reduction for Mn doped barium hexaferrite: 13.14 (1) μB/f.u. (x = 0) to 1.93 (3) μB/f.u. (x = 7) and paramagnetic behavior at room temperature for (x = 9). The transition temperature (TC) also decreases with Mn substitution, such that for x = 9, it is below room temperature. [ABSTRACT FROM AUTHOR]

Published

2020

5. PVDF Impregnated La2NiMnO6 as a New Form of Magnetoelectric Materials.

Author

Tiwary, Sweta, Kuila, S., Sahoo, M. R., Barik, A., Babu, P. D., and Vishwakarma, P. N.

Subjects

TRANSITION temperature, MAGNETIC materials, MATERIALS

Abstract

In the continuation of our recently published work [Tiwary et al., J. Appl. Phys. 124, 044101 (2018)] on triphasic La2NiMnO6, here we are reporting the magnetodielectric and magnetoelectric properties of the new form of polymer modified (4H+P) La2NiMnO6 sample. A spectrum of unusual temperature dependent transitions, are spotted in both magnetodielectric and magnetoelectric data in the temperature range of 130 to 290K. Both Positive and negative magnetodielectricity of ~5% and 12% is observed. The positive magnetodielectricity is found in the wide temperature range (130 to 270K) whereas the negative magnetodielectricity is observed nearly at the paramagnetic to ferromagnetic transition temperature of the material. The various transitions found in the Magnetodielectric are seems to be related with the magnetic ordering of the material. [ABSTRACT FROM AUTHOR]

Published

2019

6. Display of converse and direct magnetoelectric effect in double perovskite LaYFe2O6.

Author

Ghosh, R., Barik, A., Sahoo, M. R., Tiwary, Sweta, Babu, P. D., Kaushik, S. D., and Vishwakarma, P. N.

Subjects

*MAGNETOELECTRIC effect, *TRANSITION temperature, *MAGNETIC transitions, *PEROVSKITE, *NEUTRON diffraction, *MAGNETIC entropy

Abstract

This work reports the simultaneous observation of converse magnetoelectric (CME) and direct magnetoelectric (DME) effects in LaYFe2O6. The structural, magnetic, and magnetoelectric properties of LaYFe2O6, prepared by the sol-gel auto-combustion method and sintered at various temperatures, have been studied. The x-ray powder diffraction study suggests the double perovskite structure with symmetries P21nm (∼90%) and Pbnm (∼10%). The alternate ordering of La and Y ions is confirmed by the neutron powder diffraction (ND) study, which also suggests the antiferromagnetic (AFM) ordering of spins. AFM behavior is also manifested by the magnetic field-dependent magnetization (M) measurement. A higher P21nm phase content is desirable in the context of magnetoelectricity. Magnetic transition (∼700 K) is asserted in the temperature-dependent M measurement. The isothermal magnetization study shows weak ferromagnetism probably due to gradually increasing spin canting with temperature until the transition temperature. The highest CME coefficient (∼2.26 mOe cm/V) as well as DME coefficient (∼0.45 mV/cm Oe) in this material are recorded. True magnetoelectricity for temperature as high as 400 K opens up a new avenue on the playground of magnetoelectric (ME)-based applications. [ABSTRACT FROM AUTHOR]

Published

2022