Your search keyword '"magnetic moment"' showing total 47,981 results

1. Magnetic order in nanogranular iron germanium (Fe0.53Ge0.47) films.

Author

Zielinski, Ruthi, Nguyen, Nhat, Herrington, Bryce, Tarkian, Amir, Taha, Omar, Chin, Wai Kiat, Mahmood, Ather, Chen, Xiaoqian, Klewe, Christoph, Shafer, Padraic, Ciston, Jim, Ashby, Paul, Mazzoli, Claudio, and Streubel, Robert

Subjects

Physical Sciences, Condensed Matter Physics, amorphous film, topological magnetism, magnetic moment, strain, magnetic imaging, x-ray photon correlation spectroscopy, Materials Engineering, Nanotechnology, Fluids & Plasmas, Materials engineering, Condensed matter physics

Abstract

We study the effect of strain on the magnetic properties and magnetization configurations in nanogranular FexGe1-xfilms (x=0.53±0.05) with and without B20 FeGe nanocrystals surrounded by an amorphous structure. Relaxed films on amorphous silicon nitride membranes reveal a disordered skyrmion phase while films near and on top of a rigid substrate favor ferromagnetism and an anisotropic hybridization of Fedlevels and spin-polarized Gespband states. The weakly coupled topological states emerge at room temperature and become more abundant at cryogenic temperatures without showing indications of pinning at defects or confinement to individual grains. These results demonstrate the possibility to control magnetic exchange and topological magnetism by strain and inform magnetoelasticity-mediated voltage control of topological phases in amorphous quantum materials.

Published

2025

2. Electronic and Magnetic Properties of the Wurtzite Solid Solution Mn:ZnSeS.

Author

Syrotyuk, S. V., Nakonechnyi, A. Y., Klysko, Yu. V., Stepanyak, M. V., and Myshchyshyn, V. M.

Subjects

MAGNETIC structure, ELECTRONIC spectra, SOLID solutions, POLARIZED electrons, ELECTRON spin

Abstract

The the structural, electronic, and magnetic characteristics of the ZnSeS solid solution with manganese impurity have been evaluated within the DFT using the hybrid exchange-correlation functional PBE0. The structure of this solid solution was determined in two stages. At the first step the internal coordinates of atoms are optimized, and at the second one the lattice parameter relaxation, including reoptimization of internal coordinates, were done. Further, after the introduction of Mn substitution impurity, electronic energy spectra and the electronic DOS were obtained. Significant changes in parameters of the electronic structure and magnetic properties caused by the manganese impurity were found. It was established that the doped solid solution Mn:ZnSeS is a semiconductor for both electron spin polarizations. [ABSTRACT FROM AUTHOR]

Published

2024

3. Investigating magnetic proximity effects in PdCo using polarized neutron and X-ray reflectometry.

Author

Makhloufi, M., Salah, H., and Redjdal, N.

Abstract

We report on a polarized neutron reflectivity investigation of the magnetic proximity effect in PdCo bilayer. Magnetization of individual layers is measured independently, and individual hysteresis loop is inferred. The proximity effect in Si < 100 > /Pdx/Coy samples is explored as a function of layer thickness. Grazing incidence X-ray diffraction measurements were carried out to check the purity and the structure of the samples. Polarized neutron reflectometry was used to evaluate the magnetic moment. The measurements have shown a good structural quality and a surface roughness less than 0.5 nm. A net magnetization was observed from the splitting of the non-spin flip reflectivity curves. The measured Pd magnetic moment varied from 0.012 to 0.031 μB/Pd atom. In spite of the low values found, we have demonstrated the existence of a correlation between Pd magnetic moment and the thickness ratio t(Pd)/t(Co). [ABSTRACT FROM AUTHOR]

Published

2024

4. Ab-Initio Calculation of Electronic Properties of Doped GaN Nanoribbon.

Author

Ismayilova, N. A.

Subjects

*AB-initio calculations, *SPIN polarization, *MAGNETIC moments, *BAND gaps, *MAGNETIC properties

Abstract

In this study, the electronic and magnetic properties of hydrogen-passivated armchair and zigzag GaN nanoribbons are investigated using density-functional theory. We explore that doped TM atom leads to additional levels in the band gap and thus plays an essential role in spin polarization and changes their properties. Depending on its location in the nanoribbon, the character of spin-dependent electronic property of a doped GaN-NR was analyzed. Our calculations show that, regardless of the position of Mn atoms, GaNNTs are stable in ferromagnetic phase. [ABSTRACT FROM AUTHOR]

Published

2024

5. Exploring the Effect of Ce Doping on Structural, Magnetic Solar Cell and Optical Characteristics of Nano ZnMn2O4.

Author

Senguttuvan, N., Ravichandran, K., and Prakasam, A.

Subjects

*SOLAR cells, *BAND gaps, *MANGANESE oxides, *MAGNETIC moments, *CELL analysis

Abstract

This work describes the use of urea as fuel and a simple solution-based approach technique for both the pure and Ce-doped ZnMn2O4. The magnetic, structural, optical, morphological, vibrational spectroscopy and solar cell analysis were performed on the resultant materials. By increasing the Ce doping, the grain size shrank. On the other hand, the average crystallite size of pure and Ce-doped ZnMn2O4 represents 29–21 nm. The results of vibrational spectroscopy revealed that the absorption bands 450–900 cm−1 and 950–1050 cm−1 both exhibit spinal manganite formation. The morphologies of the highly uniformly distributed nanoparticles in each sample varied according to the preparation. To reach the Ce doping level, the band gap energy (1.4–2.2 eV) was lowered from the bulk to the nanoscale. M-H loops, the composites showed that cations were paramagnetic to ferromagnetic, were occupied by octahedral and tetrahedral structures. Additionally, the impact of doping on the optical and structural characteristics of various blends was investigated. This advancement suggests the application of prepared blends in various optoelectronic, electrochemical, storage devices, and solar cell applications. [ABSTRACT FROM AUTHOR]

Published

2024

6. Exploring the Effect of Ce Doping on Structural, Magnetic Solar Cell and Optical Characteristics of Nano ZnMn2O4.

Author

Senguttuvan, N., Ravichandran, K., and Prakasam, A.

Subjects

SOLAR cells, BAND gaps, MANGANESE oxides, MAGNETIC moments, CELL analysis

Abstract

This work describes the use of urea as fuel and a simple solution-based approach technique for both the pure and Ce-doped ZnMn2O4. The magnetic, structural, optical, morphological, vibrational spectroscopy and solar cell analysis were performed on the resultant materials. By increasing the Ce doping, the grain size shrank. On the other hand, the average crystallite size of pure and Ce-doped ZnMn2O4 represents 29–21 nm. The results of vibrational spectroscopy revealed that the absorption bands 450–900 cm−1 and 950–1050 cm−1 both exhibit spinal manganite formation. The morphologies of the highly uniformly distributed nanoparticles in each sample varied according to the preparation. To reach the Ce doping level, the band gap energy (1.4–2.2 eV) was lowered from the bulk to the nanoscale. M-H loops, the composites showed that cations were paramagnetic to ferromagnetic, were occupied by octahedral and tetrahedral structures. Additionally, the impact of doping on the optical and structural characteristics of various blends was investigated. This advancement suggests the application of prepared blends in various optoelectronic, electrochemical, storage devices, and solar cell applications. [ABSTRACT FROM AUTHOR]

Published

2024

7. Effect of the Number of Grains on the Magnetizationof Multi-Core Particles.

Author

Sokolsky, S. A., Solovyova, A. Yu., Elfimova, E. A., and Ivanov, A. O.

Abstract

The authors study the dependence of the static magnetic response of multi-core particles on the number of grains. The magnetization of multi-core particles consisting of grains in the nodes of a cubic lattice is determined via Monte Carlo computer modeling and theoretical calculations. It is established that the magnetization of multi-core particles is sensitive to the number of grains and does not exceed the value predicted within the single-particle Langevin model. The best agreement between the results from theoretical calculations and computer modeling is obtained for multi-core particles consisting of more than 100 grains. [ABSTRACT FROM AUTHOR]

Published

2024

8. Magnetization of Small Multi-Core Particles: Theory and Computer Modeling.

Author

Grokhotova, E. V., Solovyova, A. Yu., and Elfimova, E. A.

Abstract

The authors study the orientational texturing of the magnetic moments of four magnetic nanoparticles fixed in the vertices of a regular tetrahedron and forming a separate multi-core particle. Monte Carlo calculations are used to obtain numerically the probability density of magnetic moment orientation, static magnetization, and the initial magnetic susceptibility of a multi-core particle. [ABSTRACT FROM AUTHOR]

Published

2024

9. Testing of Theoretical Models Using Experimental Data on Magnetization of Magnetic Polymer Composites.

Author

Radushnov, D. I., Solovyova, A. Yu., Elfimova, E. A., Chernyshov, A. V., Zakinyan, A. R., and Kunikin, S. A.

Abstract

Magnetic properties of magnetic polymer composite materials were studied. Monodisperse and bidisperse theoretical models considering interparticle dipole–dipole interactions were verified using experimental data. It was determined that the bidisperse approximation well describe the experimental results for real polydisperse composites. [ABSTRACT FROM AUTHOR]

Published

2024

10. Numerical Simulation Study of The Increase in Electrical Efficiency of the CIGS-Based Solar Cell by SCAPS-1D

Author

K. Madoui, A. Ghechi, S. Madoui, R. Yekhlef, D. Belfennache, S. Zaiou, and Mohamed A. Ali

Subjects

density functional theory (dft), binding energies, homo-lumo energy, fragmentation energy, magnetic moment, Physics, QC1-999

Abstract

Solar cells are currently the focus of a great deal of research. The aim is to reduce their cost price. To achieve this, we need to reduce the mass of the materials and increase the conversion efficiency of these solar cells. This has motivated research into the use of thin films such as a-Si, CdTe, CIGS. This increase in efficiency requires optimizing the performance of the photovoltaic parameters. In this modeling and simulation work, we use the SCAPS-1D software to study the effect of the recombination speed of the electrons and holes in the CIGS layer, the effect of the thickness of the layers and the effect of the gap energy of each layer of the material used for this solar cell on the short-circuit current Jsc, the open-circuit voltage Voc, the form factor FF and the electrical efficiency η of the CIGS cell for a Mo/p-CIGS/p-Si/In2S3/i-ZnO/Al-ZnO single-junction structure. In this study, we found that recombination speed affects the efficiency of the photovoltaic cell. The gap energy of the absorber layers influences the cell's efficiency, while the other layers (In2S3, ZnO, Al-ZnO) do not have a great influence on solar cell performance and increasing the thickness of the absorber layer has a major influence on efficiency, increasing it up to a certain limit. The thicknesses of the CIGS, p-Si, In2S3, i-ZnO and Al‑ZnO layers need to be in the order of 0.3µm, 0.8µm, 0.05µm, 0.07µm and 0.1µm respectively to achieve better efficiency (31.42%).

Published

2024

11. Roles of Impurity Levels in 3d Transition Metal-Doped Two-Dimensional Ga 2 O 3.

Author

Zeng, Hui, Ma, Chao, Li, Xiaowu, Fu, Xi, Gao, Haixia, and Wu, Meng

Subjects

*ATOMIC number, *MAGNETIC moments, *INDUCTIVE effect, *FERMI level, *DOPING agents (Chemistry)

Abstract

Doping engineering is crucial for both fundamental science and emerging applications. While transition metal (TM) dopants exhibit considerable advantages in the tuning of magnetism and conductivity in bulk Ga2O3, investigations on TM-doped two-dimensional (2D) Ga2O3 are scarce, both theoretically and experimentally. In this study, the detailed variations in impurity levels within 3d TM-doped 2D Ga2O3 systems have been explored via first-principles calculations using the generalized gradient approximation (GGA) +U method. Our results show that the Co impurity tends to incorporate on the tetrahedral GaII site, while the other dopants favor square pyramidal GaI sites in 2D Ga2O3. Moreover, Sc3+, Ti4+, V4+, Cr3+, Mn3+, Fe3+, Co3+, Ni3+, Cu2+, and Zn2+ are the energetically favorable charge states. Importantly, a transition from n-type to p-type conductivity occurs at the threshold Cu element as determined by the defect formation energies and partial density of states (PDOS), which can be ascribed to the shift from electron doping to hole doping with respect to the increase in the atomic number in the 3d TM group. Moreover, the spin configurations in the presence of the square pyramidal and tetrahedral coordinated crystal field effects are investigated in detail, and a transition from high-spin to low-spin arrangement is observed. As the atomic number of the 3d TM dopant increases, the percentage contribution of O ions to the total magnetic moment significantly increases due to the electronegativity effect. Additionally, the formed 3d bands for most TM dopants are located near the Fermi level, which can be of significant benefit to the transformation of the absorbing region from ultraviolet to visible/infrared light. Our results provide theoretical guidance for designing 2D Ga2O3 towards optoelectronic and spintronic applications. [ABSTRACT FROM AUTHOR]

Published

2024

12. First-principles study of the structural, electronic, magnetic and elastic properties of YxGd1-xN alloys.

Author

Bouhadef, Bachir, Talbi, Khedija, Ghezali, Mohamed, and Cherchab, Youcef

Subjects

*ELECTRONIC band structure, *TERNARY alloys, *ENERGY levels (Quantum mechanics), *BAND gaps, *FERMI energy

Abstract

The structural stability, electronic structure, and optical properties of the novel YxGd1-xN ternary alloys were studied using the FP-LAPW method with the generalized gradient approximation + Hubbard U (GGA + U). Our results reveal that YxGd1-xN alloys can be experimentally synthesized because they exhibit energetic and mechanical stability. All these systems present semiconducting behavior. Both GdN and YN are indirect band gap semiconductors while YxGd1-xN alloys are direct band gap semiconductors for $x = 0.25\comma \; 0.5\comma \; 0.75$ x = 0.25 , 0.5 , 0.75 because of hybridization between d (Y) and Gd(f) orbitals in the vicinity of the Fermi energy level. The f-d coupling induces the major magnetic moments on the Gd atom. The absorption spectra are reasonably high (>105 cm−1) and the bandgap energy and structure spacing match between YN and GaN which made YxGd1-xN alloys suitable for optoelectronic applications. In the absence of experimental work, our results can be useful for further studies. [ABSTRACT FROM AUTHOR]

Published

2024

13. Two K20 microwave dielectric ceramics SrLnAlO4 (Ln = Eu, Gd) with near-zero τf and contrasting Q×f.

Author

Wang, Sijie, Fang, Weishuang, Wu, Daofu, Meng, Kuiyi, Tang, Ying, Yang, Junfeng, Ding, Mingjian, Lin, Huixing, and Fang, Liang

Subjects

*CERAMICS, *MOLECULAR polarizability, *DIELECTRICS, *MICROWAVES, *MAGNETIC moments, *VALENCE bonds

Abstract

K20 microwave dielectric ceramics SrLnAlO 4 (Ln = Eu, Gd, and Ho) were prepared at 1440–1520 °C. SrEuAlO 4 and SrGdAlO 4 crystallized into tetragonal K 2 NiF 4 -type structures. While SrHoAlO 4 was a mixture (SrHo 2 Al 2 O 7 , Ho 2 O 3 , and Sr 3 HoAl 2 O 7.5) due to the too-small radius of Ho3+ to bond in [HoO 9 ] dodecahedron. SrEuAlO 4 and SrGdAlO 4 exhibited near-zero τ f values of +1.7 and +4.3 ppm/°C and low ε r (19.37 and 19.14) along with contrasting Q × f values (70,030 and 5560 GHz). Compared with the modified molecular polarizability (α Corr) based on the bond valence deviation, the α obs values of SrEuAlO 4 and SrGdAlO 4 are much higher, indicating that their dielectric polarizabilities were underestimated, and this phenomenon was mainly influenced by rattling cations, which also causes their τ f with near-zero values. Due to the magnetic subsystem adversely affecting microwave dielectric losses, the worsened Q × f value of SrGdAlO 4 compared to that of SrEuAlO 4 is due to the high magnetic moment of Gd3+ (7.94 μ B). [ABSTRACT FROM AUTHOR]

Published

2024

14. Using Evolutionary Algorithms and Ab Initio Calculations to Study the Crystal Structure of Intercalated Fe1/3TiS2 Compound.

Author

Chubarova, A. A. and Mamonova, M. V.

Abstract

Ab initio calculations of the crystal structure and magnetic properties of intercalated Fe0.33TiS2 compound are made using evolutionary machine learning algorithms. Spin‒orbit interaction is considered, and the band structure and density of states are calculated. [ABSTRACT FROM AUTHOR]

Published

2024

15. Modeling Residual Magnetic Anomalies of Landmines Using UAV-Borne Vector Magnetometer: Flight Simulations and Experimental Validation.

Author

Lee, Junghan and Lee, Haengseon

Subjects

*MAGNETIC anomalies, *DRONE aircraft, *MAGNETIC moments, *LAND mines, *MAGNETOMETERS

Abstract

This study presents an unmanned aerial vehicle (UAV)-borne vector magnetometer (MAG) system and proposes a new data-processing technique for modeling the residual magnetic anomalies of three types of landmines: the metallic antitank M15, the metallic antipersonnel M16, and the minimum-metal antitank M19. The burial depth and magnetic moment of these landmines were estimated using the measured and simulated residual magnetic anomalies based on the proposed UAV-borne vector MAG model. Initial in-flight validation showed a strong correlation between the residual magnetic anomaly maps obtained from measurements and simulations. To verify the detection capability in real-world conditions, the UAV-borne MAG system was tested at the Korean Combat Training Center. Both simulations and experiments demonstrated the effectiveness of the proposed data-processing method and UAV-borne MAG model in accurately modeling the residual magnetic anomalies of landmines with metallic components. This approach will facilitate the automated detection of M15, M16, and M19 landmines with high detection rates and enable accurate classification. [ABSTRACT FROM AUTHOR]

Published

2024

16. In situ synthesis of magnetite on carbon fiber surface.

Author

Ivanova, E. V., Lebedeva, E. A., Trukhinov, D. K., Lebedev, A. V., Balasoiu, M., and Astaf'eva, S. A.

Subjects

*CARBON fibers, *MAGNETIC moments, *MAGNETIC properties, *MAGNETIC particles, *MAGNETITE

Abstract

A simple and affordable in situ synthesis of a carbon fiber@magnetite hybrid for use as a filler in shielding polymer materials is proposed. The presence of magnetic particles on the carbon fiber was confirmed by X-ray diffraction, and the effect of modification on the structural properties of the components and the magnetic properties of the system was analyzed. The analysis of the structural characteristics and the magnetic properties of the components obtained during the synthesis process was carried out. The modification of the surface of the carbon fiber with magnetite made it possible to obtain for the resulting hybrid a magnetic moment value that is three times higher than that of a mechanical mixture of carbon fiber and magnetite with the same composition. [ABSTRACT FROM AUTHOR]

Published

2024

17. NUMERICAL SIMULATION STUDY OF THE INCREASE IN ELECTRICAL EFFICIENCY OF THE CIGS-BASED SOLAR CELL BY SCAPS-1D.

Author

Madoui, K., Ghechi, A., Madoui, S., Yekhlef, R., Belfennache, D., Zaiou, S., and Ali, Mohamed A.

Subjects

*SOLAR cells, *DENSITY functional theory, *MAGNETIC moments, *SILICON, *PHYSICS periodicals

Abstract

Solar cells are currently the focus of a great deal of research. The aim is to reduce their cost price. To achieve this, we need to reduce the mass of the materials and increase the conversion efficiency of these solar cells. This has motivated research into the use of thin films such as a-Si, CdTe, CIGS. This increase in efficiency requires optimizing the performance of the photovoltaic parameters. In this modeling and simulation work, we use the SCAPS-1D software to study the effect of the recombination speed of the electrons and holes in the CIGS layer, the effect of the thickness of the layers and the effect of the gap energy of each layer of the material used for this solar cell on the short-circuit current Jsc, the open-circuit voltage Voc, the form factor FF and the electrical efficiency η of the CIGS cell for a Mo/p-CIGS/p-Si/In2S3/i-ZnO/Al-ZnO single-junction structure. In this study, we found that recombination speed affects the efficiency of the photovoltaic cell. The gap energy of the absorber layers influences the cell's efficiency, while the other layers (In2S3, ZnO, Al-ZnO) do not have a great influence on solar cell performance and increasing the thickness of the absorber layer has a major influence on efficiency, increasing it up to a certain limit. The thicknesses of the CIGS, p-Si, In2S3, i-ZnO and Al-ZnO layers need to be in the order of 0.3µm, 0.8µm, 0.05µm, 0.07µm and 0.1µm respectively to achieve better efficiency (31.42%). [ABSTRACT FROM AUTHOR]

Published

2024

18. Predicting the stability and exploring the fundamental physical properties of tetragonal Gd2O3: A comprehensive first-principles investigation

Author

Minhajul Islam and Md Abdur Rob Sheikh

Subjects

Burnable absorber, Tetragonal Gd2O3, GGA, Magnetic moment, Thermal conductivity, Nuclear engineering. Atomic power, TK9001-9401

Abstract

A burnable absorber is a material used in nuclear reactors to manage reactivity and extend operational cycles by absorbing neutrons. Gadolinium oxide (Gd2O3) is a prevalent burnable absorber employed in nuclear reactors. By utilizing density functional theory (DFT) within a first-principles framework, a comprehensive exploration into the physical characteristics of the predicted tetragonal phase of Gd2O3 has been effectively conducted. The investigation encompasses structural, electronic, magnetic, elastic, mechanical, bonding, thermophysical, and optical aspects. Since tetragonal Gd2O3 has not been experimentally synthesized, the stability of the tetragonal phase is confirmed through assessments of its structural, lattice dynamical, thermodynamic, and mechanical attributes. Demonstrating semiconducting behavior, the electronic nature reveals a band gap of 1.241 eV. The density of states (DOS) illustration validates the semiconductor electronic character, and the calculated magnetic moment, determined through up-down spin DOS, is 3.06 μB/f.u. The Poisson’s ratio value reflects the dominance of ionic bonding in Gd2O3, a finding corroborated by bond population analysis. Impressively, the tetragonal Gd2O3 displays elevated lattice thermal conductivity value in comparison to its cubic, monoclinic, and hexagonal counterparts. Furthermore, the determined melting point registers at 1709.31 K. In the realm of optics, an analysis based on frequency dependence reveals that tetragonal Gd2O3 holds promise as a candidate for optoelectronic applications, particularly in the ultraviolet (UV) energy range.

Published

2024

19. Behavior of Magnetic Nanoparticles in the Phantom of the Biological Medium

Author

Ichkitidze, L. P., Filippova, O. V., Belodedov, M. V., Galechyan, G. Yu., Savelyev, M. S., Gerasimenko, A. Yu., Telyshev, D. V., Selishchev, S. V., Ghosh, Arindam, Series Editor, Chua, Daniel, Series Editor, de Souza, Flavio Leandro, Series Editor, Aktas, Oral Cenk, Series Editor, Han, Yafang, Series Editor, Gong, Jianghong, Series Editor, Jawaid, Mohammad, Series Editor, Parinov, Ivan A., editor, Chang, Shun-Hsyung, editor, and Putri, Erni Puspanantasari, editor

Published

2024

20. Exploring the Effect of Ce Doping on Structural, Magnetic Solar Cell and Optical Characteristics of Nano ZnMn2O4

Author

Senguttuvan, N., Ravichandran, K., and Prakasam, A.

Published

2024

21. Aromatic and magnetic properties in a series of heavy rare earth‐doped Ge6 cluster anions.

Author

Zhang, Jia‐Ming, Wang, Huai‐Qian, Li, Hui‐Fang, Mei, Xun‐Jie, Zeng, Jin‐Kun, Qin, Lan‐Xin, Zheng, Hao, Zhang, Yong‐Hang, Jiang, Kai‐Le, Zhang, Bo, and Wu, Wen‐Hai

Subjects

*MAGNETIC properties, *RARE earth metals, *RARE earth oxides, *DENSITY functional theory, *MAGNETIC moments, *SEMICONDUCTOR materials, *CHARGE transfer

Abstract

A series of pentagonal bipyramidal anionic germanium clusters doped with heavy rare earth elements, REGe6− (RE = Gd, Tb, Dy, Ho, Er, Tm, Yb, and Lu), have been identified at the PBE0/def2‐TZVP level using density functional theory (DFT). Our findings reveal that the centrally doped pentagonal ring structure demonstrates enhanced stability and heightened aromaticity due to its uniform bonding characteristics and a larger charge transfer region. Through natural population analysis and spin density diagrams, we observed a monotonic decrease in the magnetic moment from Gd to Yb. This is attributed to the decreasing number of unpaired electrons in the 4f orbitals of the heavy rare earth atoms. Interestingly, the system doped with Er atoms showed lower stability and anti‐aromaticity, likely due to the involvement of the 4f orbitals in bonding. Conversely, the systems doped with Gd and Tb atoms stood out for their high magnetism and stability, making them potential building blocks for rare earth‐doped semiconductor materials. [ABSTRACT FROM AUTHOR]

Published

2024

22. Spin-Orbit Interaction During the Activation of Molecular Oxygen by Oxidases and Cofactor-Free Oxygenases: A Review.

Author

Minaev, B. P., Sakhno, T. V., Panchenko, O. O., and Sakhno, Y. E.

Subjects

*SPIN-orbit interactions, *GLUCOSE oxidase, *OXYGENASES, *MAGNETIC moments, *OXIDASES, *COFACTORS (Biochemistry), *DIOXYGENASES

Abstract

The current state of research on spin-orbit interaction in cofactor-free oxidases and dioxygenases during oxygen activation is considered. The spin activation of triplet oxygen during combustion and respiration is analyzed in comparison with the reactions of flavin-containing enzymes, as well as important cofactor-independent dioxygenases. The mechanism of the triplet-singlet transition in glucose oxidase and a number of dioxygenases, including the RuBisCo oxygenase pathway and chirality-induced spin selectivity, is considered. [ABSTRACT FROM AUTHOR]

Published

2024

23. Computational and experimental approach for investigation of optical properties of single-crystal MnGa2Se4.

Author

Ismayilova, N.A., Asadullayeva, S.G., Musayev, M.A., and Askerov, D.J.

Subjects

*OPTICAL properties, *DENSITY functional theory, *MAGNETIC moments, *ABSORPTION coefficients, *CRITICAL point (Thermodynamics), *BAND gaps

Abstract

In the presented work, we propose a systematic investigation of the electronic and optical properties of MnGa2Se4 by combining the spectroscopic ellipsometry carried out at room temperature in the spectral range of 1–4 eV and density functional theory (DFT) calculations. Ellipsometric measurements were collected at an incidence angle between 60° and 75° with a 5° step. The optical direct gap energies of MnGa2Se4 were estimated from the linear extrapolation of the absorption coefficients that were verified by band structure calculation. DFT calculation of the imaginary part ɛ shows that first critical point occurs at 2.46 eV and represents the direct optical transition at Γ point. The total magnetic moment of compound is 3.38 mB. The major contribution in total magnetic moment is due to 3d state of Mn atoms. [ABSTRACT FROM AUTHOR]

Published

2024

24. Magnetic Properties of Multicomponent (Er1 –xYx)0.8Sm0.2Fe2 Alloys.

Author

Umkhaeva, Z. S., Karpenkov, A. Yu., Tereshina, I. S., Pankratov, N. Yu., and Aliev, I. M.

Abstract

New (Er1 –xYx)0.8Sm0.2Fe2 multicomponent alloys with a substitution parameter of x = 0, 0.2, 0.4, 0.6, 0.8, and 1.0 are synthesized and their atomic crystal structure and magnetic properties are studied. It is shown that full magnetic compensation can be expected in the region of 0.2 < xcomp < 0.4. Er0.8Sm0.2Fe2 alloy exhibits temperature-dependent magnetization compensation at Tcomp = 400 K. [ABSTRACT FROM AUTHOR]

Published

2024

25. Computational and experimental approach for investigation of optical properties of single-crystal MnGa2Se4.

Author

Ismayilova, N.A., Asadullayeva, S.G., Musayev, M.A., and Askerov, D.J.

Subjects

OPTICAL properties, DENSITY functional theory, MAGNETIC moments, ABSORPTION coefficients, CRITICAL point (Thermodynamics), BAND gaps

Abstract

In the presented work, we propose a systematic investigation of the electronic and optical properties of MnGa2Se4 by combining the spectroscopic ellipsometry carried out at room temperature in the spectral range of 1–4 eV and density functional theory (DFT) calculations. Ellipsometric measurements were collected at an incidence angle between 60° and 75° with a 5° step. The optical direct gap energies of MnGa2Se4 were estimated from the linear extrapolation of the absorption coefficients that were verified by band structure calculation. DFT calculation of the imaginary part ɛ shows that first critical point occurs at 2.46 eV and represents the direct optical transition at Γ point. The total magnetic moment of compound is 3.38 mB. The major contribution in total magnetic moment is due to 3d state of Mn atoms. [ABSTRACT FROM AUTHOR]

Published

2024

26. STUDY ON MAGNETIC PROPERTIES OF FeCoPSiBCu AMORPHOUS ALLOY BY EMPIRICAL ELECTRON THEORY.

Author

WU, XIAOYU, GUO, XUANXUAN, GU, YUE, LI, SHENGLI, and LI, XUE

Abstract

In this study, a new evaluation method was investigated for the magnetic properties of the amorphous alloys by comparing the experimental results with the theoretical calculations. First, The (Fe70Co6P4.8Si9.6B9.6)100−xCux (x=0–0.5) amorphous ribbons were prepared by melt spinning method. Then, the magnetic properties of the prepared amorphous alloys were measured as 165.86–147.04emu/g, respectively. On the other side, we analyzed the valence electron structure and obtained the magnetizations as 159.92–158.77emu/g by calculating the magnetic moments of unit cells based on empirical electron theory (EET) of solids and molecules. Through comparing the magnetic properties of the calculations with the measurements, we found that the differences between the calculations and the measurements are less than 12% for all samples, meeting the first approximation requirement. Moreover, with the addition of Cu, the change trends both in the calculated and measured magnetic properties are also consistent. These results prove that it is feasible to calculate the magnetic property of the amorphous alloy from the valence electron level using EET, which provides a new method to investigate the soft magnetic property of the amorphous alloy instead of the real measurement. [ABSTRACT FROM AUTHOR]

Published

2024

27. Features of magnetic structure and properties of ceramics (1 − x)Pb(Fe1/2Nb1/2)o3—xPb(Fe2/3W1/3)o3.

Author

Glazunova, E. V., Kubrin, S. P., Shilkina, L. A., Lis, O. N., Nagaenko, A. V., Verbenko, I. A., Kichanov, S. E., Rutkauskas, A. V., and Reznichenko, L. A.

Subjects

*MAGNETIC structure, *SOLID-phase synthesis, *MAGNETIC moments, *MOSSBAUER spectroscopy, *SOLID solutions

Abstract

We studied solid solutions of the system (1−x)PbFe1/2Nb1/2O3 - xPbFe2/3W1/3O3 using X-ray and Neuron diffraction, and Mössbauer spectroscopy. To obtain ceramics, we used the method of two-stage solid-phase synthesis and sintering according to the conventional ceramic technology. Pure solid solutions of the (1−x)PbFe1/2Nb1/2O3-xPbFe2/3W1/3O3 system were obtained. A deviation of the unit cell parameters from the Vegard rule was revealed, which indicates stratification of the structure into microregions differing in composition. The introduction of PbFe2/3W1/3O3 into the system led to partial ordering (clustering) of cations in the B position. An increase in magnetic moment with growing amount of PbFe2/3W1/3O3 was shown. [ABSTRACT FROM AUTHOR]

Published

2024

28. Features of magnetic structure and properties of ceramics (1 − x)Pb(Fe1/2Nb1/2)o3—xPb(Fe2/3W1/3)o3.

Author

Glazunova, E. V., Kubrin, S. P., Shilkina, L. A., Lis, O. N., Nagaenko, A. V., Verbenko, I. A., Kichanov, S. E., Rutkauskas, A. V., and Reznichenko, L. A.

Subjects

MAGNETIC structure, SOLID-phase synthesis, MAGNETIC moments, MOSSBAUER spectroscopy, SOLID solutions

Abstract

We studied solid solutions of the system (1−x)PbFe1/2Nb1/2O3 - xPbFe2/3W1/3O3 using X-ray and Neuron diffraction, and Mössbauer spectroscopy. To obtain ceramics, we used the method of two-stage solid-phase synthesis and sintering according to the conventional ceramic technology. Pure solid solutions of the (1−x)PbFe1/2Nb1/2O3-xPbFe2/3W1/3O3 system were obtained. A deviation of the unit cell parameters from the Vegard rule was revealed, which indicates stratification of the structure into microregions differing in composition. The introduction of PbFe2/3W1/3O3 into the system led to partial ordering (clustering) of cations in the B position. An increase in magnetic moment with growing amount of PbFe2/3W1/3O3 was shown. [ABSTRACT FROM AUTHOR]

Published

2024

29. Ab Initio Study of the Physical Properties of Cs-Based Double Perovskites Cs2AX6 (A = Ge, Mn; X = Cl, I).

Author

YAHAYA, A. A., YAHYA, W. A., AHMED, A. S., and SHOLAGBERU, A. A.

Subjects

*PEROVSKITE, *BAND gaps, *ELECTRIC conductivity, *SEEBECK coefficient, *THERMOELECTRIC materials, *CESIUM

Abstract

Device applications in magnetic media, spintronics, oxygen membranes, sensors, etc., are some of the uses of ferrite materials. In this work, we have studied the structural, electronic, magnetic, mechanical, and thermoelectric properties of Cs-based double perovskites Cs2AX6 (A = Ge, Mn; X = Cl, I), using Quantum Espresso with generalized gradient approximation Perdew-Burke-Ernzerhof and Perdew-Burke-Ernzerhof in solids exchange-correlation functionals. The band structure results show that Cs2GeCl6 and Cs2MnCl6 are semiconductors with direct band gaps. However, there are bands crossing observed for Cs2GeI6 from the conduction band minimum to the valence band maximum, indicating the metallic nature of the material. Moreover, Cs2MnI6 has magnetic properties; it exhibits a metallic nature in the spin-up state and a semiconductor nature in the spin-down state, suggesting that it can be used in spintronics applications. The calculated total magnetic moment of Cs2MnCl6 is 3:0μB (for both Perdew-Burke-Ernzerhof and Perdew-Burke-Ernzerhof in solids), while for Cs2MnI6, the calculated total magnetic moments are 3:02μB and 3:06μB, for Perdew-Burke-Ernzerhof and Perdew-Burke-Ernzerhof in solids exchange-correlation functionals, respectively. The results of the mechanical properties calculations show that Cs-based double perovskites Cs2AX6 (A = Ge, Mn; X = Cl, I) are mechanically stable. Cauchy's pressure and Poisson's, Frantsevich's, and Pugh's ratios of the studied materials confirm that Cs2MnCl6 is brittle, while the remaining studied double perovskite materials are ductile. Electrical conductivity, thermal conductivity, Seebeck coefficients, power factor, and figure of merit are the thermoelectric parameters analyzed in this study. Seebeck coefficients, electrical conductivity, and power factor increase with the rise in temperature, and Cs2MnX6 (X = Cl, I) double perovskite materials have higher values of electrical conductivity than Cs2GeX6 (X = Cl, I). All the studied materials have positive type conductivity due to their positive Seebeck coefficient values. [ABSTRACT FROM AUTHOR]

Published

2024

30. Transient radiation of magnetic moment in plane-layered dielectric.

Author

Aliyeva, Mina Baylar

Abstract

The transient radiation of the magnetic moment in the plane-layered medium is considered. In order, to determine the electromagnetic field of the magnetic moment, in contrast to the known method of the field vectors, for the first time, the electric and magnetic Hertzian vectors are introduced as initial functions which turns out to be the most efficient for calculating the field amplitudes. This method can also be applied to calculate the field and power of the Cherenkov radiation of a charged particle with a magnetic dipole moment. The expressions are obtained for the Eigen field and the radiation field of a magnetic moment moving in media whose permittivity changes smoothly in the direction of motion. The radiation fields are estimated and the contribution of the magnetic transient radiation to the radiation of the particle is found. In particular, it is shown that in the interplanetary medium (in the ionosphere) the contribution of magnetic transient radiation becomes more significant in the ultra-relativistic case, in the region of small angles. The obtained results can be considered at the development of the devices for registration and identification of easy charged particles, having the magnetic moment: transient radiation detectors, and also for definition of transient radiation role in earth atmosphere and earth core, which are considered as plane-layered ones. [ABSTRACT FROM AUTHOR]

Published

2024

31. Mass and Magnetic Moment of the Electron and the Stability of QED—A Critical Review

Author

Michael Bordag and Irina G. Pirozhenko

Subjects

QED, electron mass, magnetic moment, Physics, QC1-999

Abstract

The anomalous magnetic moment of the electron, first calculated by Schwinger, lowers the ground state energy of the electron in a weak magnetic field. It is a function of the field and changes signs for large fields, ensuring the stability of the ground state. This has been shown in the past 50 years in numerous papers. The corresponding corrections to the mass of the electron have also been investigated in strong fields using semiclassical methods. We critically review these developments and point out that the calculation for low-lying excited states raises questions. Also, we calculate the contribution from the tadpole diagram, the relevance of which was observed only quite recently.

Published

2024

32. Theoretical insight into the stability, magneto-electronic and thermodynamic properties of the new half-metallic ferromagnetic compounds Cr2RbZ (Z=Ge, In and Sb): probed by DFT

Author

Asfour, I.

Published

2024

33. Using Evolutionary Algorithms and Ab Initio Calculations to Study the Crystal Structure of Intercalated Fe1/3TiS2 Compound

Author

Chubarova, A. A. and Mamonova, M. V.

Published

2024

34. Examining Computationally the Physical Properties of Novel Lead-Free Eco-Friendly Chloroperovskites for Energy Applications

Author

Irfan, Muhammad, Ahmed, Emad M., Issa, Shams A. M., and Zakaly, Hesham M. H.

Published

2024

35. In-gas-cell laser ionization spectroscopy at KISS

Author

Hirayama, Yoshikazu, Mukai, Momo, Watanabe, Yutaka, Schury, Peter, Niwase, Toshitaka, Choi, Hyunsuk, Hashimoto, Takashi, Iimura, Shun, Jeong, SunChan, Miyatake, Hiroari, Moon, JunYoung, Nakada, Hitoshi, Oyaizu, Michihiro, Rosenbusch, Marco, Takamine, Aiko, Tajima, Minori, Taniguchi, Akihiro, and Wada, Michiharu

Published

2024

36. Rabi-oscillation spectroscopy of the hyperfine structure of the muonium atom for high-precision determination of the muon mass

Author

Torii, Hiroyuki A.

Published

2024

37. Simulation of the Features of the Magnetic Properties of Axisummetric Granules of Hard Type II Superconductors.

Author

Kuzmichev, N. D., Shushpanov, A. A., and Vasyutin, M. A.

Subjects

*ELECTROMAGNETIC induction, *MAGNETIC moments, *MAGNETIC fields, *MAGNETIC properties, *HYSTERESIS loop, *FLUX pinning

Abstract

Based on the equations of electrodynamics and the concept of a critical state for hard superconductors of the 2nd kind, numerical simulation of the magnetic properties of axisymmetric superconducting samples, in particular, granules, is performed for a number of models of the dependence of the critical current density on the magnetic field induction. The magnetic moment loops are calculated directly by integrating the integral equation for the current density over time. The phenomena of the peak effect and the asymmetry of the magnetization hysteresis loop are also considered using the indicated equation. Various versions of the functions used in the literature were used as peak functions. In addition to the hysteresis loop of the magnetic moment, the magnetic field induction at the center of axisymmetric samples, and the total penetration field, the profiles of the critical current density Jc(B) and the equilibrium magnetic moment for spherical granules were obtained. The method used for calculating the magnetic moment of superconductors makes it possible to take into account the equilibrium and nonequilibrium regions of the magnetization of the samples independently. [ABSTRACT FROM AUTHOR]

Published

2024

38. Mass and Magnetic Moment of the Electron and the Stability of QED—A Critical Review.

Author

Bordag, Michael and Pirozhenko, Irina G.

Subjects

*MAGNETIC moments, *ELECTRON energy states, *GROUND state energy, *ELECTRONS, *EXCITED states, *QUANTUM electrodynamics

Abstract

The anomalous magnetic moment of the electron, first calculated by Schwinger, lowers the ground state energy of the electron in a weak magnetic field. It is a function of the field and changes signs for large fields, ensuring the stability of the ground state. This has been shown in the past 50 years in numerous papers. The corresponding corrections to the mass of the electron have also been investigated in strong fields using semiclassical methods. We critically review these developments and point out that the calculation for low-lying excited states raises questions. Also, we calculate the contribution from the tadpole diagram, the relevance of which was observed only quite recently. [ABSTRACT FROM AUTHOR]

Published

2024

39. Magnetic and thermoelectric properties of REMoN3 (RE = La, Ce, Pr, Nd, and Sm): A first‐principles study.

Author

Haq, Saeed Ul, Muhammad, Raz, Alqorashi, Afaf Khadr, Shafiullah, Muhammad, Sohail, Amir, Laref, Amel, and Faizan, Muhammad

Subjects

*THERMOELECTRIC materials, *MAGNETIC properties, *MAGNETIC moments, *RARE earth metals, *PEROVSKITE, *DIGITAL maps

Abstract

We investigated the magnetic and thermoelectric properties of REMoN3 (RE = La, Ce, Pr, Nd, Sm) perovskites using the full potential linearized augmented plane wave (FP‐LAPW) method. To overcome the problem of underestimation of electronic interaction, we employed the DFT + U approach to accurately map the electronic structure of these compounds. Our study shows an increasing trend in the magnetic moments with the increasing number of unpaired electrons in RE. Among these compounds, SmMoN3 possesses a large magnetic moment, which is suitable for applications such as memory devices and sensors. Interestingly, all these perovskites display ferromagnetic behavior except CeMoN3, which exhibits an antiferromagnetic nature. Furthermore, our analysis indicates n‐type thermoelectric behavior in all these materials. The compound, namely PrMoN3, exhibits a high figure of merit among REMoN3, which can be improved by modifying the lattice sites. [ABSTRACT FROM AUTHOR]

Published

2024

40. Magnetic-biased chiral molecules enabling highly oriented photovoltaic perovskites.

Author

Chen, Jing, Deger, Caner, Su, Zhen-Huang, Wang, Kai-Li, Zhu, Guang-Peng, Wu, Jun-Jie, He, Bing-Chen, Chen, Chun-Hao, Wang, Tao, Gao, Xing-Yu, Yavuz, Ilhan, Lou, Yan-Hui, Wang, Zhao-Kui, and Liao, Liang-Sheng

Subjects

*PEROVSKITE, *MAGNETIC dipole moments, *MAGNETIC entropy, *OPEN-circuit voltage, *MOLECULES, *FORMAMIDINES, *PASSIVATION

Abstract

The interaction between sites A, B and X with passivation molecules is restricted when the conventional passivation strategy is applied in perovskite (ABX3) photovoltaics. Fortunately, the revolving A-site presents an opportunity to strengthen this interaction by utilizing an external field. Herein, we propose a novel approach to achieving an ordered magnetic dipole moment, which is regulated by a magnetic field via the coupling effect between the chiral passivation molecule and the A-site (formamidine ion) in perovskites. This strategy can increase the molecular interaction energy by approximately four times and ensure a well-ordered molecular arrangement. The quality of the deposited perovskite film is significantly optimized with inhibited nonradiative recombination. It manages to reduce the open-circuit voltage loss of photovoltaic devices to 360 mV and increase the power conversion efficiency to 25.22%. This finding provides a new insight into the exploration of A-sites in perovskites and offers a novel route to improving the device performance of perovskite photovoltaics. [ABSTRACT FROM AUTHOR]

Published

2024

41. Ab Initio Simulation of the Energy of the α-Fe/Fe3C Interphase Boundary with Bagaryatsky Orientation Relationships.

Author

Verkhovykh, A. V., Mirzoev, A. A., Okishev, K. Yu., and Dyuryagina, N. S.

Abstract

Pearlite is one of the fundamental structural components of carbon and low-alloy steels. In pearlite, the orientation relationships of Bagaryatsky, Isaychev, and Pitsch can be observed between the body-centered cubic ferritic and rhombic cementite Fe3C phases. In low-temperature pearlite, which exhibits the highest strength, the first two predominate, and they are closely related, sometimes indistinguishable in experiments. In this study, ab initio simulation using density functional theory in the WIEN2k software package is conducted to investigate the structures and energies of coherent α-Fe/Fe3C interphase boundaries. The supercells undergo structural and volume optimization. Calculations of the interphase boundary surface energy yield values of 0.383 and 0.594 J/m2 for the Bagaryatsky and Isaychev orientation relationships, respectively. These results align well with existing experimental values and outcomes from other molecular dynamics and ab initio calculations. The difference in the surface energy may play a significant role in low-temperature pearlite with thin plates of ferrite and cementite and a large interphase-boundary area per unit volume. [ABSTRACT FROM AUTHOR]

Published

2024

42. Sensing behavior of various gas molecules adsorbed on Fe-doped and bare antimonene armchair nanoribbon.

Author

Kashani, Sharareh Hasanpour, Barvestani, Jamal, and Meshginqalam, Bahar

Subjects

*DOPING agents (Chemistry), *ELECTRON donors, *MAGNETIC moments, *DENSITY functional theory, *CHARGE transfer, *MOLECULES

Abstract

First-principles calculations, using density functional theory, have been studied to investigate the sensing of NO2, NO, N2, CO2, CO, O2, NH3 and SO2 gases on bare and Fe-doped antimonene armchair nanoribbons (Fe-doped ASbNRs). The sensing behaviors of these gases on bare and Fe-doped ASbNRs have been analyzed in terms of band structure, the density of states, adsorption energy, charge transfer, magnetic moments and I–V characteristics. We showed that doping the magnetic Fe atom increases the sensing ability of antimonene nanoribbon where the gas molecules are chemisorption on Fe-doped ASbNR. This chemisorption induces dramatic change in the adsorption energy and electronic structures, and injects magnetic moments into the nanoribbon system. The NO molecule depicts the tightest binding in the Fe-doped ASbNRs. Charge transfer analysis of adsorbates demonstrates that all gas molecules, except NO, NH3 and CO are electron donors to nanoribbon. Transport properties of Fe-doped ASbNRs transistor, display desirable I–V characteristics and spin filter efficiency for the NO2, N2, and NH3 gases. These two-dimensional systems may possess the potential in the promising application of gas sensing. [ABSTRACT FROM AUTHOR]

Published

2024

43. Investigating the electronic structure, magnetic, and optical properties of the KCrS half Heusler compound from first principles.

Author

Saleh, Rabab A. and AL-Zyadi, Jabbar M.

Abstract

Copyright of Journal of Basrah Researches (Sciences) is the property of Republic of Iraq Ministry of Higher Education & Scientific Research (MOHESR) and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

44. Electronic and Magnetic Properties of the Solid Solution Cr: ZnSeTe with the Cationic Vacancy.

Author

Syrotyuk, S. V., Nakonechnyi, A. Y., Klysko, Yu. V., Veres, Z. E., and Lahun, I. I.

Subjects

SOLID solutions, MAGNETIC properties, ELECTRONIC density of states, MAGNETIC structure, ELECTRON spin, CATIONIC polymers

Abstract

The focus of this study is the structural, electronic, and magnetic characteristics of the ZnSeTe solid solution with chromium impurity. The structure of this solid solution was determined in two steps. At the first stage the internal coordinates of atoms are optimized, and at the second one the lattice parameter relaxation, including re-optimization of internal coordinates, were done. Further, after the introduction of Cr substitution impurity, electronic energy spectra and densities of electronic states were calculated. Significant changes in parameters of the electronic structure and magnetic properties caused by cationic vacancy were revealed. It was found that the doped solid solution of Cr:ZnSeTe is a semiconductor for both electron spin polarizations. The study of the supercell with a cationic vacancy revealed significant differences in the parameters of electronic energy bands as well as magnetic properties, compared with those in crystal with no defects. [ABSTRACT FROM AUTHOR]

Published

2024

45. Magnetic moment of Mn2+ ions that are responsible for the ferromagnetic properties of ZnO:Mn nanocrystals

Author

O.V. Kovalenko and V.Yu. Vorovsky

Subjects

magnetic moment, nanocrystals, ultrasonic aerosol pyrolysis, heat treatment, hydrogen, Physics, QC1-999

Abstract

The calculation of the magnetic moment of Mn2+ ions in ZnO:Mn (2 at%.) nanocrystals obtained by ultrasonic pyrolysis of aerosol which are responsible for their ferromagnetic properties is given. In order to investigate the influence of structural defects on the value of magnetic moment the samples were heat treated in air. The calculation was performed on the basis of the analysis of magnetization curves and EPR spectra. It was shown that the defective state of ZnO:Mn nanocrystals has a significant effect on the magnetic moment. The values of magnetic moment for the synthesized sample significantly exceed the values of magnetic moment compared to similar nanocrystals obtained by other methods. The assumption is made that this result is due to the presence of an additional component in the magnetization of the defective samples. In addition to the paramagnetism of Mn2+ ions, there may be the paramagnetism of the defective shell of ZnO:Mn nanocrystals. After the elimination of structural defects by heat treatment of samples in air and in a gas mixture with hydrogen, the magnetic moment for Mn2+ ions, which form the ferromagnetic properties of nanocrystals, was determined. The value of this magnetic moment is 0.02µB, where µB is the Bohr mangiton. Such ions, according to the model of bound magnetic polarons, are part of ferromagnetic clusters and take part in the formation of the ferromagnetic properties of the samples. Keywords: magnetic moment, nanocrystals, ultrasonic aerosol pyrolysis, heat treatment, hydrogen.

Published

2023

46. Modeling Residual Magnetic Anomalies of Landmines Using UAV-Borne Vector Magnetometer: Flight Simulations and Experimental Validation

Author

Junghan Lee and Haengseon Lee

Subjects

UAV-borne magnetometer, minimum-metal landmine, residual magnetic anomaly, burial depth, magnetic moment, Science

Abstract

This study presents an unmanned aerial vehicle (UAV)-borne vector magnetometer (MAG) system and proposes a new data-processing technique for modeling the residual magnetic anomalies of three types of landmines: the metallic antitank M15, the metallic antipersonnel M16, and the minimum-metal antitank M19. The burial depth and magnetic moment of these landmines were estimated using the measured and simulated residual magnetic anomalies based on the proposed UAV-borne vector MAG model. Initial in-flight validation showed a strong correlation between the residual magnetic anomaly maps obtained from measurements and simulations. To verify the detection capability in real-world conditions, the UAV-borne MAG system was tested at the Korean Combat Training Center. Both simulations and experiments demonstrated the effectiveness of the proposed data-processing method and UAV-borne MAG model in accurately modeling the residual magnetic anomalies of landmines with metallic components. This approach will facilitate the automated detection of M15, M16, and M19 landmines with high detection rates and enable accurate classification.

Published

2024

47. Quantization of the Angular Momentum

Author

Santamaria, Ruben and Santamaria, Ruben

Published

2023

48. Fe3O4

Author

Kawazoe, Yoshiyuki, Kanomata, Takeshi, Note, Ryunosuke, Kawazoe, Yoshiyuki, Kanomata, Takeshi, and Note, Ryunosuke

Published

2023

49. V2O3

Author

Kawazoe, Yoshiyuki, Kanomata, Takeshi, Note, Ryunosuke, Kawazoe, Yoshiyuki, Kanomata, Takeshi, and Note, Ryunosuke

Published

2023

50. UO2

Author

Kawazoe, Yoshiyuki, Kanomata, Takeshi, Note, Ryunosuke, Kawazoe, Yoshiyuki, Kanomata, Takeshi, and Note, Ryunosuke

Published

2023