Browsing by Author "Pakhira, S"
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- ItemComplex magnetic properties associated with competing local and itinerant magnetism in Pr2Co0.86Si2.88(Springer Nature, 2021-06-24) Kundu, M; Pakhira, S; Choudhary, R; Paudyal, D; Lakshminarasimhan, N; Avdeev, M; Cottrell, SP; Adroja, DT; Ranganathan, R; Mazumdar, CTernary intermetallic compound Pr2Co0.86Si2.88 has been synthesized in single phase and characterized by x-ray diffraction, scanning electron microscopy with energy dispersive x-ray spectroscopy (SEM-EDX) analysis, magnetization, heat capacity, neutron diffraction and muon spin rotation/relaxation (μSR) measurements. The polycrystalline compound was synthesized in single phase by introducing necessary vacancies in Co/Si sites. Magnetic, heat capacity, and zero-field neutron diffraction studies reveal that the system undergoes magnetic transition below ∼4 K. Neutron diffraction measurement further reveals that the magnetic ordering is antiferromagnetic in nature with an weak ordered moment. The high temperature magnetic phase has been attributed to glassy in nature consisting of ferromagnetic clusters of itinerant (3d) Co moments as evident by the development of internal field in zero-field μSR below 50 K. The density-functional theory (DFT) calculations suggest that the low temperature magnetic transition is associated with antiferromagnetic coupling between Pr 4f and Co 3d spins. Pr moments show spin fluctuation along with unconventional orbital moment quenching due to crystal field. The evolution of the symmetry and the crystalline electric field environment of Pr-ions are also studied and compared theoretically between the elemental Pr and when it is coupled with other elements such as Co. The localized moment of Pr 4f and itinerant moment of Co 3d compete with each other below ∼20 K resulting in an unusual temperature dependence of magnetic coercivity in the system. This article is licensed under a Creative Commons Attribution 4.0 International License.
- ItemHigh spin polarization in the disordered quaternary Heusler alloy FeMnVGa(American Physical Society, 2023-07-25) Gupta, S; Chakraborty, S; Bhasin, V; Pakhira, S; Dan, S; Barreteau, C; Crivello, JC; Jha, SN; Avdeev, M; Greneche, JM; Bhattacharyya, D; Alleno, E; Mazumdar, CIn this paper, we report the successful synthesis of a Fe-based highly spin-polarized quaternary Heusler alloy FeMnVGa and its structural, magnetic, and transport properties probed through different experimental methods and theoretical techniques. Density functional theory (DFT) calculations performed on different types of structures reveal that the structure with Ga at 4a, V at 4b, Mn at 4c, and Fe at 4d (space group F¯43m) possess minimum energy among all the ordered variants. Ab initio simulations in the most stable ordered structure show that the compound is a ferromagnet having a large spin-polarization (89.9%). Neutron diffraction reveals that the compound crystallizes in disordered type-2 structure (space group Fm¯3m) in which Ga occupies at 4a, V 4b and Fe/Mn occupy 4c/4d sites with 50:50 proportions. The structural disorder is further confirmed by x-ray diffraction, extended x-ray absorption fine structure, 57Fe Mössbauer spectrometry results, and DFT calculations. Magnetization studies suggest that the compound orders ferromagnetically below TC∼293 K and the saturation magnetization follows the Slater-Pauling rule. Mössbauer spectrometry, along with neutron diffraction, suggest that Mn is the major contributor to the total magnetism in the compound, consistent with the theoretical calculations, which also indicates that spin polarization remains high (81.3%), even in the presence of such large atomic disorder. The robustness of the half-metallic ferromagnetic (HMF) property in the presence of disorder is a quite unique characteristic over other reported HMF in literature and makes this compound quite promising for spintronics applications. ©2023 American Physical Society.
- ItemHigh spin-polarization in a disordered novel quaternary Heusler alloy FeMnVGa(Cornell University, 2023-03-15T12:51:40Z) Gupta, S; Chakraborty, S; Bhasin, V; Pakhira, S; Dan, S; Barreteau, C; Crivello, JC; Jha, SN; Avdeev, M; Greneche, JM; Bhattacharyya, D; Alleno, E; Mazumdar, CIn this work, we report the successful synthesis of a Fe-based novel half-metallic quaternary Heusler alloy FeMnVGa and its structural, magnetic and transport properties probed through different experimental methods and theoretical technique. Density functional theory (DFT) calculations performed on different types of structure reveal that Type-2 ordered structure (space group: F-43m, Ga at 4a, V at 4b, Mn at 4c and Fe at 4d) possess minimum energy among all the ordered variants. Ab-initio simulations in Type 2 ordered structure further reveal that the compound is half-metallic ferromagnet (HMF) having a large spin-polarization (89.9 %). Neutron diffraction reveal that the compound crystalizes in disordered Type-2 structure (space group: Fm-3m) in which Ga occupy at 4a, V at 4b and Fe/Mn occupy 4c/4d sites with 50:50 proportions. The structural disorder is further confirmed by X-ray diffraction (XRD), extended X-ray absorption fine structure (EXAFS),57Fe Mossbauer spectrometry results and DFT calculations. Magnetisation studies suggest that the compound orders ferromagnetically below TC ~ 293 K and the saturation magnetization follows Slater-Pauling rule. Mossbauer spectrometry, along with neutron diffraction suggest that Mn is the major contributor to the total magnetism in the compound consistent with the theoretical calculations. First principle calculations indicate that spin-polarization remain high (81.3 %) even in the presence of such large atomic disorder. The robustness of the HMF property in presence of disorder is a quite unique characteristic over other reported HMF in literature and make this compound quiet promising for spintronics applications.
- ItemLarge magnetic cooling power involving frustrated antiferromagnetic spin-glass state in R 2 NiSi 3 (R= Gd, Er)(American Physical Society, 2016-09-14) Pakhira, S; Mazumdar, C; Ranganathan, R; Giri, S; Avdeev, MThe ternary intermetallic compounds Gd2NiSi3 and Er2NiSi3 are synthesized in chemically single phase, which are characterized using dc magnetization, ac magnetic susceptibility, heat capacity, and neutron diffraction studies. Neutron diffraction and heat capacity studies confirm that long-range magnetic ordering coexists with the frustrated glassy magnetic components for both compounds. The static and dynamical features of dc magnetization and frequency-dependent ac susceptibility data reveal that Gd2NiSi3 is a canonical spin-glass system, while Er2NiSi3 is a reentrant spin cluster-glass system. The spin freezing temperature merges with the long-range antiferromagnetic ordering temperature at 16.4 K for Gd2NiSi3. Er2NiSi3 undergoes antiferromagnetic ordering at 5.4 K, which is slightly above the spin freezing temperature at 3 K. The detailed studies of nonequilibrium dynamical behavior, viz., the memory effect and relaxation behavior using different protocols, suggest that both compounds favor the hierarchical model over the droplet model. A large magnetocaloric effect is observed for both compounds. Maximum values of isothermal entropy change (−ΔSM) and relative cooling power (RCP) are found to be 18.4 J/kg K and 525 J/kg for Gd2NiSi3 and 22.6 J/kg K and 540 J/kg for Er2NiSi3, respectively, for a change in field from 0 to 70 kOe. The values of RCP are comparable to those of the promising refrigerant materials. A correlation between large RCP and magnetic frustration is discussed for developing new magnetic refrigerant materials. ©2016 American Physical Society
- ItemMagnetic frustration induced large magnetocaloric effect in the absence of long range magnetic order(Springer Nature, 2017-08-04) Pakhira, S; Mazumdar, C; Ranganathan, R; Avdeev, MWe have synthesized a new intermetallic compound Ho2Ni0.95Si2.95 in a single phase with a defect crystal structure. The magnetic ground state of this material found to be highly frustrated without any long range order or glassy feature as investigated through magnetic, heat capacity and neutron diffraction measurements. The interest in this material stems from the fact that despite the absence of true long range order, large magnetocaloric effect (isothermal magnetic entropy change, −ΔSM ~ 28.65 J/Kg K (~205.78 mJ/cm3 K), relative cooling power, RCP ~ 696 J/Kg (~5 J/cm3) and adiabatic temperature change, ΔT ad ~ 9.32 K for a field change of 70 kOe) has been observed which is rather hard to find in nature. © 2017 The Authors
- ItemMagnetic structure of triangular lattice compound Tb2Ni0.90Si2.94(Elsevier, 2021-10-15) Pakhira, S; Morozkin, AV; Avdeev, M; Mazumdar, CAlB2-type ternary intermetallic compound Tb2Ni0.90Si2.94 (space group P6/mmm,hP3, No. 191) was reported to exhibit spin freezing behaviour of the ferromagnetic clusters present in the system below Tf=9.9 K, along with the presence of spatially limited antiferromagnetic phase. In this work, on the basis of variable temperature zero-field neutron diffraction measurements, we have shown that the antiferromagnetic phase transition occurs for the compound below TN~13 K. Neutron diffraction study indicates ab-plane non-collinear sine-modulated antiferromagnetic ordering of the system with wave vectors of k1=[±1/6,±1/6,0] and k2=[±1/3,±1/3,0] down to 1.7 K. The weak and diffuse nature of the magnetic Bragg peaks along with limited coherence length further confirm the short-range nature of the antiferromagnetic phase in this compound. © 2021 Elsevier B.V.
- ItemModification of magnetic ground state in Tb2Ni0. 90Si2. 94 by thermal annealing(Elsevier, 2020-09-01) Pakhira, S; Bhowmik, RN; Avdeev, M; Ranganathan, R; Mazumdar, CIn this work, we have investigated the thermal annealing effect on the physical properties of an AlB-type ternary intermetallic compound, TbNi0.90Si2.94, that undergoes spin freezing behaviour coexisting with spatially limited antiferromagnetic phase below 9.9 K in as-cast form. Thermal annealing effect is found to result in considerable changes in the magnetic ground state properties of the system. Though only one magnetic transition around 9.9 K is observed for as-cast compound, the annealed sample exhibits two distinct magnetic transitions; one around 13.5 K and another around 4 K. The magnetization measurements and zero field neutron diffraction study reveal that the high temperature transition is antiferromagnetic type, though of limited correlation length, while the low temperature transition corresponds to spin freezing behaviour. The ac susceptibility and heat capacity studies also confirm the existence of frustrated cluster glass state at lower temperature than the antiferromagnetic ordering temperature. Additionally, ac susceptibility data exhibits signature of an additional peak in the even lower temperature region (at 2.2 K for zero frequency) that tends to shift in opposite direction with frequency in contrast to that observed for conventional glassy transitions. The change in intrinsic local structural disorder of Ni and Si ions associated with annealing has been argued to be responsible for the different magnetic behaviour in as-cast and annealed samples. Published by Elsevier Ltd.
- ItemObservation of charge transfer induced large enhancement of magnetic moment in a structurally disordered inverse Heusler alloy Fe2RuGe(American Physical Society (APS), 2023-12-01) Chakraborty, S; Gupta, S; Bhasin, V; Pakhira, S; Barreteau, C; Crivello, JC; Jha, SN; Bhattacharyya, D; Avdeev, M; Paul-Boncour, V; Greneche, JM; Alleno, E; Mazumdar, CWe report the successful synthesis of a new 4d-based polycrystalline inverse Heusler alloy Fe2RuGe by an arc melting process and have studied in detail its structural, magnetic and transport properties complemented with first-principles calculations. X-ray and neutron diffraction, extended x-ray absorption fine structure, and 57Fe Mössbauer spectroscopic studies confirm the single-phase nature of the system where the Fe and Ru atoms are randomly distributed in the 4c and 4d Wyckoff positions in a ratio close to 50:50. The formation of the disordered structure is also confirmed by the theoretical energy minimization calculation. Despite the random cross-site disorder of Fe and Ru atoms, magnetic measurements suggest not only a high Curie temperature of ∼860 K, but also a large saturation magnetic moment ∼4.9µB per formula unit at 5 K, considerably exceeding the theoretical limit (4 µB per formula unit) predicted by the Slater-Pauling rule. Only a few Fe-based inverse Heusler alloys are known to exhibit such high Curie temperatures. Neutron diffraction analysis coupled with the isothermal magnetization value indicates that the magnetic moments in Fe2RuGe are associated with Fe atoms only, which is also confirmed by Mössbauer spectrometry. Interestingly, in comparison to the cubic or hexagonal phase of the parent compound, Fe3Ge, the Curie temperature of Fe2RuGe has increased significantly despite the substitution of the nonmagnetic yet isoelectronic element Ru in this structurally disordered compound. Our theoretical calculation reveals that the large Fe moment (∼2.8µB/Fe) on the 4b site can be attributed to a charge transfer from this Fe site towards its Ru neighbors while a significant moment (∼2µB/Fe) is kept on the other Fe sites. Instead of expected Slater-Pauling value of 4µB/f.u., the substantially increased observed total magnetic moment of ∼4.9µB/f.u. is due to these electron charge transfers, which have not been previously reported in other ferromagnetic Heusler systems. © 2024 American Physical Society.
- ItemSpatially limited antiferromagnetic order in a cluster glass compound Tb2Ni0.90Si2.94(Elsevier, 2019-05-15) Pakhira, S; Mazumdar, C; Avdeev, M; Bhowmik, RN; Ranganathan, RIn the present study, the synthesis of a new ternary intermetallic compound Tb2Ni0.90Si2.94 has been reported. The detailed studies on structure, static and dynamical magnetic properties of the compound have been investigated by means of powder x-ray diffraction, compositional analysis, dc & ac magnetization, non-equilibrium dynamics, heat capacity and neutron diffraction measurements. The dc & ac magnetic susceptibility reveal that the compound undergoes spin cluster-glass behaviour below 9.9 K. The frequency dependence of the freezing temperature have been analysed on the basis of dynamic scaling laws such as power-law divergence and Vogel-Fulcher law, which further confirm the cluster-glass state formation for the compound. A detailed study on non-equilibrium dynamical behaviour associated with cluster-glass state has been carried out through magnetic relaxation behaviour along with magnetic memory effect in zero-field-cooled (ZFC) as well as field-cooled (FC) conditions and associated aging effect. The zero-field neutron diffraction study reveals the presence of a spatially limited antiferromagnetic phase in addition to the magnetically frustrated cluster-glass state. This result has also been supported through zero-field heat capacity studies. The variation in local electronic environment among the magnetic rare-earth ions caused by the structural disorder associated with Ni/Si ions have been argued to be responsible for the coexistence of different magnetic phases. © 2019 Elsevier B.V.