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1. Correlation stabilized ferromagnetic MnRuAs with distorted kagome lattice

Author

C V, Anusree, Ptok, Andrzej, Sobieszczyk, Paweł, Vaitheeswaran, G., and Kanchana, V.

Subjects
Condensed Matter - Materials Science, Condensed Matter - Strongly Correlated Electrons
Abstract

We present an in-depth analysis of MnRuAs, a compound crystallizing in the P$\bar{6}$2m symmetry with a distorted kagome lattice, revealing its distinctive structural, magnetic, and electronic properties through state-of-the-art ab initio calculations. By incorporating strong correlation effects using the DFT+U approach, we demonstrate the stabilization of MnRuAs, transforming its inherent dynamical instability into a robust ferromagnetic state with significant coupling along the $c$ axis. The calculated magnon dispersion reveals a parabolic profile with a minimum at the $\Gamma$ point, indicative of ferromagnetic behavior. Furthermore, MnRuAs exhibits intriguing electronic properties, including quasi-one-dimensional Fermi surface and the formation of nodal sphere. Our study also delves into the electronic surface states and constant energy contours, offering valuable insights into the complex physics of this material., Comment: 14 pages, 8 figures + supplement: 6 pages and 9 figures

Published
2025
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4. Electronic structure and physical properties of candidate topological material GdAgGe

Author

Ram, D., Singh, J., Hooda, M. K., Pavlosiuk, O., Kanchana, V., Hossain, Z., and Kaczorowski, D.

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We grew needle-shaped single crystals of GdAgGe, which crystallizes in a noncentrosymmetric hexagonal crystal structure with space group P$\overline{6}$2$m$ (189). The magnetic susceptibility data for $H \perp c$ reveal two pronounced antiferromagnetic transitions at $T_{N1}$ = 20 K and $T_{N2}$ = 14.5 K. The magnetic susceptibility anomalies are less prominent for $H \parallel c$. The transition at $T_{N1}$ is accompanied by a pronounced heat capacity anomaly confirming the bulk nature of the magnetic transition. Below $T_{N1}$, the electrical resistivity data follows a $T^{3/2}$ dependence. In the magnetically ordered state, GdAgGe shows positive transverse magnetoresistance, which increases with decreasing temperature and increasing field, reaching a value of $\sim$ 27% at 9 T and 10 K. The Hall resistivity data and electronic band structure calculations suggest that both the hole and electron charge carriers contribute to the transport properties. The electronic band structure displays linear band crossings near the Fermi level. The calculations reveal that GdAgGe has a nodal line with drumhead surface states coupled with a nonzero Berry phase, making it a nontrivial nodal-line semimetal., Comment: 9 pages, 9 figures

Published
2024
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5. Multiple magnetic transitions, metamagnetism and large magnetoresistance in GdAuGe single crystals

Author

Ram, D., Singh, J., Hooda, M. K., Singh, K., Kanchana, V., Kaczorowski, D., and Hossain, Z.

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science
Abstract

We report the physical properties of GdAuGe single crystals, which were grown using Bi flux. The powder x-ray diffraction data shows that the compound crystallizes in hexagonal NdPtSb-type structure (space group P63mc). Magnetization measurements performed for field configuration H||c and H||ab show that GdAuGe orders antiferromagnetically at the Neel temperature, TN = 17.2 K. Around this temperature, heat capacity and electrical resistivity data exhibit prominent anomaly due to the antiferromagnetic (AFM) transition. In addition to an AFM phase transition, the magnetization data for H||c display the signature of field-induced metamagnetic (MM) transitions below TN. The critical field range for these transitions vary from 0.2 to 6.2 T. The critical fields for the MM transitions decrease with increasing temperature and approach zero value for temperature approaching TN. Interestingly, the magnetoresistance (MR) data (for H||c) record a sharp increase in values at the critical fields that coincide with those seen in magnetization data, tracking the presence of MM transitions. MR is positive and large (169% at 9 T and 2 K) at low temperatures. Above TN, MR becomes small and switches to negative values. Hall resistivity data reveal the predominance of hole charge carriers in the system. In addition, we observe an emergence of step-like feature in the Hall resistivity data within the field range of second MM, and a significantly large anomalous Hall conductivity of 1270 {\Omega}-1 cm-1 at 2 K. The H-T phase diagram constructed from our detailed magnetization and magnetotransport measurements reveals multiple intricate magnetic phase transitions. The electronic and magnetic structure of GdAuGe are also thoroughly investigated using first-principles methods. The electronic band structure calculations reveal that GdAuGe is a Dirac nodal-line semimetal., Comment: 11 pages, 12 figures

Published
2023
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8. Exploring magnetism, topology, and magnetoresistance in rare-earth-based compound GdAuSn: Ab initio study.

Author

Mondal, Sumit, Singh, Jaspreet, and Kanchana, V.

Subjects
ELECTRONIC band structure, ENERGY levels (Quantum mechanics), PARTICLE size determination, HEISENBERG model, TOPOLOGICAL property
Abstract

Rare-earth intermetallics, especially Gd-based compounds, are of great interest due to their diverse magnetic ground states and intriguing topological properties. Using first-principles calculations, we investigate the magnetic, electronic, and phononic properties of GdAuSn. Our results identify the C -type antiferromagnetic configuration as the lowest energy state, with a critical temperature of 25 K estimated using the Heisenberg spin model and mean-field approximation. The electronic band structure reveals nodal surfaces and Dirac points, highlighting the material's non-trivial topology. In the magnetically ordered state, GdAuSn exhibits positive transverse magnetoresistance, increasing to ∼ 25% at 3.5 T and 10 K, with Hall resistivity analysis confirming electron-dominated transport. Additionally, phonon dispersion analysis uncovers topological phononic states with nodal surfaces. These findings provide insights into the interplay of magnetism, topology, and transport in GdAuSn, establishing its potential for fundamental research and topological antiferromagnetic spintronics. [ABSTRACT FROM AUTHOR]

Published
2024
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9. Electronic structure and physical properties of EuAuAs single crystal

Author

Malick, S., Singh, J., Laha, A., Kanchana, V., Hossain, Z., and Kaczorowski, D.

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

High-quality single crystals of EuAuAs were studied by means of powder x-ray diffraction, magnetization, magnetic susceptibility, heat capacity, electrical resistivity and magnetoresistance measurements. The compound crystallizes with a hexagonal structure of the ZrSiBe type (space group $P6_3/mmc$). It orders antiferromagnetically below 6 K due to the magnetic moments of divalent Eu ions. The electrical resistivity exhibits metallic behavior down to 40 K, followed by a sharp increase at low temperatures. The magnetotransport isotherms show a distinct metamagnetic-like transition in concert with the magnetization data. The antiferromagnetic ground state in \mbox{EuAuAs} was corroborated in the \textit{ab initio} electronic band structure calculations. Most remarkably, the calculations revealed the presence of nodal line without spin-orbit coupling and Dirac point with inclusion of spin-orbit coupling. The \textit{Z}$_2$ invariants under the effective time reversal and inversion symmetries make this system nontrivial topological material. Our findings, combined with experimental analysis, makes EuAuAs a plausible candidate for an antiferromagnetic topological nodal-line semimetal.

Published
2022
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10. Experimental and theoretical study of the correlated compound YbCdSn: Evidence for large magnetoresistance and mass enhancement

Author

Laha, Antu, Rambabu, P., Kanchana, V., Petit, L., Szotek, Z., and Hossain, Z.

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

The unusual features of topological semimetals arise from its nontrivial band structure. The impact of strong electron correlations on the topological states remains largely unexplored in real materials. Here, we report the magnetotransport properties of YbCdSn single crystals. We found two fundamental experimental evidences of electron correlations through magnetic susceptibility and specific heat. The electron correlations in this compound lead to an intermediate valence state and enhance the effective mass of the charge carriers. This correlated state exhibits large nonsaturating magnetoresistance, low carrier density, magnetic field induced metal-semiconductor-like crossover and a plateau in resistivity at low temperatures. This compound also shows a cusp-like magnetoconductivity at low magnetic field which indicates the presence of weak antilocalization effect. Our band structure calculations of Yb$^{2+}$ state predict YbCdSn to be a topological nodal-line semimetal., Comment: 10 Pages, 8 Figures, Published, Phys. Rev. B

Published
2020
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16. Ferromagnetically correlated clusters in semi-metallic Ru2NbAl Heusler alloy

Author

Mondal, Sanchayita, Mazumdar, Chandan, Ranganathan, R., Alleno, Eric, Sreeparvathy, P. C., Kanchana, V., and Vaitheeswaran, G.

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

In this work, we report the structural, magnetic and electrical and thermal transport properties of the Heusler-type alloy Ru2NbAl. From the detailed analysis of magnetization data, we infer the presence of superparamagnetically interacting clusters with a Pauli paramagnetic background, while short-range ferromagnetic interaction is developed among the clusters below 5 K. The presence of this ferromagnetic interaction is confirmed through heat capacity measurements. The relatively small value of electronic contribution to specific heat, gamma (~2.7 mJ/mol-K2), as well as the linear nature of temperature dependence of Seebeck coefficient indicate a semi-metallic ground state with a pseudo-gap that is also supported by our electronic structure calculations. The activated nature of resistivity is reflected in the observed negative temperature coefficient and has its origin in the charge carrier localization due to antisite defects, inferred from magnetic measurements as well as structural analysis. Although the absolute value of thermoelectric figure of merit is rather low (ZT = 5.2*10-3) in Ru2NbAl, it is the largest among all the reported non-doped full Heusler alloys., Comment: 25 pages, 14 figures

Published
2018
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21. Switching of the topologically trivial and non-trivial quantum phase transitions in compressed 1T-TiTe2: Experiments and Theory

Author

Rajaji, V., Dutta, Utpal, Sreeparvathy, P. C., Sarma, Saurav Ch., Sorb, Y. A., Joseph, B., Sahoo, Subodha, Peter, Sebastian C., Kanchana, V., and Narayana, Chandrabhas

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

We report the structural, vibrational and electrical transport properties up to 16 GPa of the 1T-TiTe2, a prominent layered 2D system, which is predicted to show a series of topologically trivial - nontrivial transitions under hydrostatic compression. We clearly show signatures of two iso-structural transition at 2 GPa and 4 GPa obtained from the minima in c/a ratio concomitant with the phonon linewidth anomalies of Eg and A1g modes at around the same pressures, providing strong indication of unusual electron-phonon coupling associated to these transitions. Resistivity presents nonlinear behavior over similar pressure ranges providing a strong indication of the electronic origin of these pressure driven isostructural transitions. Our data thus provide clear evidences of topological changes at A and L point of the Brillouin zone predicted to be present in the compressed 1T-TiTe2. Between 4 GPa and 8 GPa, the c/a ratio shows a plateau suggesting a transformation from an anisotropic 2D layer to a quasi 3D crystal network. First principles calculations suggest that the 2D to quasi 3D evolution without any structural phase transitions is mainly due to the increased interlayer Te-Te interactions (bridging) via the charge density overlap. In addition to the pressure dependent isostructural phase transitions, our data also evidences the occurrence of a first order structural phase transition from the trigonal (P-3m1) phase at higher pressures. We estimate the start of this structural phase transition to be 8 GPa and the symmetric of the new high-pressure phase to be monoclinic (C2/m)., Comment: 22 pages, 11 Figures, 2 Tables

Published
2017
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24. Predicted thermoelectric properties of olivine-type Fe2GeCh4 (Ch = S, Se and Te)

Author

Gudelli, Vijay Kumar, Kanchana, V, and Vaitheeswaran, G

Subjects
Condensed Matter - Materials Science
Abstract

We present here the thermoelectric properties of olivine-type Fe2GeCh4 (Ch = S, Se and Te) using the linear augmented plane wave method based on first principles density functional calculations. The calculated transport properties using the semi-local Boltzmann transport equation reveal very high thermopower for both S and Se-based compounds compared to their Te counterparts. The main reason for this high thermopower is the quasi-flat nature of the bands at the valence and conduction band edges. The calculated thermopower of Fe2GeCh4 is in good agreement with the experimental reports at room temperature, with the carrier concentration around 1018-1019cm-3. All the investigated systems show an anisotropic nature in their electrical conductivity, resulting in a value less than the order of 102 along the a-axis compared to the b- and c-axes. Among the studied compounds, Fe2GeS4 and Fe2GeSe4 emerge as promising candidates with good thermoelectric performance., Comment: 21 pages, 9 figures, Published in Journal

Published
2016
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25. Electronic topological transitions in Nb$_3$X (X = Al, Ga, In, Ge and Sn) under compression investigated by first principles calculations

Author

Reddy, P. V. Sreenivasa, Kanchana, V., Vaitheeswaran, G., Modak, P., and Verma, Ashok K.

Subjects
Condensed Matter - Materials Science
Abstract

First principles electronic structure calculations of A-15 type Nb$_3$X (X = Al, Ga, In, Ge and Sn) compounds are performed at ambient and high pressures. Mechanical stability is confirmed in all the compounds both at ambient as well as under compression from the calculated elastic constants. We have observed four holes and two electron Fermi surfaces (FS) for all the compounds studied and FS nesting feature is observed at M and along X - $\Gamma$ in all the compounds. A continuous change in the FS topology is observed under pressure in all the compounds which is also reflected in the calculated elastic constants and density of states under pressure indicating the Electronic topological transitions (ETT). The ETT observed at around 21.5 GPa, 17.5 GPa in Nb$_3$Al and Nb$_3$Ga are in good agreement with the anomalies observed by the experiments., Comment: 19 pages, 17 figures

Published
2016
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26. Predicted superconductivity of Ni2VAl and pressure dependence of superconductivity in Ni2NbX (X = Al, Ga and Sn) and Ni2VAl

Author

Reddy, P V Sreenivasa, Kanchana, V, Vaitheeswaran, G, and Singh, David J

Subjects
Condensed Matter - Superconductivity
Abstract

A first-principles study of the electronic and superconducting properties of the Ni$_2$VAl Heusler compound is presented. The electron-phonon coupling constant of $\lambda_{ep}$ = 0.68 is obtained, which leads to a superconducting transition temperature of T$_c$ = $\sim$4 $K$ (assuming a Coulomb pseudopotential $\mu^*$ = 0.13), which is a relatively high transition temperature for Ni based Heusler alloys. The electronic density of states reveals a significant hybridization between Ni-$eg$ and V-$t_{2g}$ states around the Fermi level. The Fermi surface, consisting of two electron pockets around the X-points of the Brillouin zone, exhibits nesting and leads to a Kohn anomaly of the phonon dispersion relation for the transverse acoustic mode TA2 along the (1,1,0) direction, which is furthermore found to soften with pressure. As a consequence, T$_c$ and $\lambda_{ep}$ vary non-monotonically under pressure. The calculations are compared to similar calculations performed for the Ni$_2$NbX (X = Al, Ga and Sn) Heusler alloys, which experimentally have been identified as superconductors. The experimental trend in T$_c$ is well reproduced, and reasonable quantitative agreement is obtained. The calculated T$_c$ of Ni$_2$VAl is larger than either calculated and observed T$_c$s of any of the Nb compounds. The Fermi surfaces of Ni$_2$NbAl and Ni$_2$NbGa consist of only a single electron pocket around the X point, however under compression second electron pocket similar to that of Ni2VAl emerges only in Ni2NbAl and the Tc increases non monotonically in all the compounds. Fermi surface nesting and associated Kohn anomalies are a common feature of all four compounds, albeit weakest in Ni$_2$VAl., Comment: 22 pages, 10 figures

Published
2016
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28. Electronic Structure, Transport and Phonons of SrAg$Ch$F ($Ch$=S, Se, Te): Bulk Superlattice Thermoelectrics

Author

Gudelli, Vijay Kumar, Kanchana, V., Vaitheeswaran, G., Singh, David J., Svane, A., Christensen, N. E., and Mahanti, Subhendra D.

Subjects
Condensed Matter - Materials Science
Abstract

We report calculations of the electronic structure, vibrational properties and transport for the p-type semiconductors, SrAg$Ch$F ($Ch$=S, Se and Te). We find soft phonons with low frequency optical branches intersecting the acoustic modes below 50 $cm^{-1}$, indicative of a material with low thermal conductivity. The bands at and near the valence band maxima are highly two dimensional, which leads to high thermopowers even at high carrier concentrations, which is a combination that suggests good thermoelectric performance. These materials may be regarded as bulk realizations of superlattice thermoelectrics.

Published
2015
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29. CuAlTe$_2$: A promising bulk thermoelectric material

Author

Gudelli, Vijay Kumar, Kanchana, V., and Vaitheeswaran, G.

Subjects
Condensed Matter - Materials Science
Abstract

Transport properties of Cu-based chalcopyrite materials are presented using the full potential linear augmented plane wave method and Boltzmann Semi-classical theory. All the studied compounds appear to be direct band gap semiconductors evaluated based on the Tran-Blaha modified Becke-Johnson potential. The heavy and light band combination found near the valence band maximum (VBM) drive these materials to possess good thermoelectric properties. Among the studied compounds, CuAlTe$_2$ is found to be more promising, in comparison with CuGaTe$_2$, which is reported to be an efficient thermoelectric material with appreciable figure of merit. Another interesting fact about CuAlTe$_2$ is the comparable thermoelectric properties possessed by both $n-$ type and $p-$ type carriers, which might attract good device applications and are explained in detail using the electronic structure calculations.

Published
2015
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32. High Pressure Structural Stability, and Optical Properties of Scheelite type ZrGeO$_4$ and HfGeO$_4$ X-ray Phosphor Hosts

Author

Shwetha, G., Kanchana, V., Babu, K. Ramesh, Vaitheeswaran, G., and Valsakumar, M. C.

Subjects
Condensed Matter - Materials Science
Abstract

\emph{Ab-initio} calculations were performed on the scheelite type MGeO$_4$ (M = Hf, and Zr) compounds which find wide range of applications such as in x-ray imaging. We have studied the high pressure structural stability, elastic constants, electronic structure and optical properties of these compounds through density functional theory calculations. Two different density functional approaches namely plane wave pseudopotential method (PW-PP) and full potential linearized augmented plane wave method (FP-LAPW) were used for the present study. The ground state structural and vibrational properties are calculated and found to be in good agreement with experimental data. The compressibility of Zr and Hf germanates is found to be anisotropic as the a-axis is less compressible over c-axis due to the presence of Ge-O bonds along a-axis which is further confirmed from the ordering of the elastic constants that follows C$_{11}$ $>$ C$_{33}$. The electronic structure of the compounds has been calculated through recently developed Tran Blaha-modified Becke Johnson potential. The calculated electronic structure shows that the compounds are insulators with a gap of 5.39 eV for ZrGeO$_4$ and 6.25 eV for HfGeO$_4$ respectively. Optical anisotropy of these compounds are revealed from the computed optical properties such as complex dielectric function, refractive index, and absorption coefficient. In addition, it is observed that Ti doped ZrGeO$_4$ and HfGeO$_4$ turns out to be a good phosphor as the pristine compounds have the energy gap greater than the visible range upon Ti doping bandgap reduces as a result emission spectra occurs in the visible region and is well explained in the present study.

Published
2014

33. Thermoelectric properties of marcasite and pyrite FeX$_2$(X=Se,Te): A first principle study

Author

Gudelli, Vijay Kumar, Kanchana, V., Vaitheeswaran, G., Valsakumar, M. C., and Mahanti, S. D.

Subjects
Condensed Matter - Materials Science
Abstract

Electronic structure and thermoelectric properties of marcasite (m) and synthetic pyrite (p) phases of FeX$_2$ (X=Se,Te) have been investigated using first principles density functional theory and Boltzmann transport equation. The plane wave pseudopotential approximation was used to study the structural properties and full-potential linear augmented plane wave method was used to obtain the electronic structure and thermoelectric properties (thermopower and power factor scaled by relaxation time). From total energy calculations we find that m-FeSe$_2$ and m-FeTe$_2$ are stable at ambient conditions and no structural transition from marcasite to pyrite is seen under the application of hydrostatic pressure. The calculated ground state structural properties agree quite well with available experiments. From the calculated thermoelectric properties, we find that both m and p forms are good candidates for thermoelectric applications. However, hole doped m-FeSe$_2$ appears to be the best among all the four systems.

Published
2014

34. Thermoelectric properties of chalcopyrite type CuGaTe$_2$ and chalcostibite CuSbS$_2$

Author

Gudelli, Vijay Kumar, Kanchana, V., Vaitheeswaran, G., Svane, A., and Christensen, N. E.

Subjects
Condensed Matter - Materials Science
Abstract

Electronic and transport properties of CuGaTe$_2$, a hole-doped ternary copper based chalcopyrite type semiconductor, are studied using calculations within the Density Functional Theory and solving the Boltzmann transport equation within the constant relaxation time approximation. The electronic bandstructures are calculated by means of the full-potential linear augmented plane wave method, using the Tran-Blaha modified Becke-Johnson potential. The calculated band gap of 1.23 eV is in agreement with the experimental value of 1.2 eV. The carrier concentration- and temperature dependent thermoelectric properties of CuGaTe$_2$ are derived, and a figure of merit of $zT= 1.69$ is obtained at 950 K for a hole concentration of $3.7\cdot10^{19}$ cm$^{-3}$, in agreement with a recent experimental finding of $zT= 1.4$, confirming that CuGaTe$_2$ is a promising material for high temperature thermoelectric applications. The good thermoelectric performance of p-type CuGaTe$_2$ is associated with anisotropic transport from a combination of heavy and light bands. Also for CuSbS$_2$ (chalcostibite) a better performance is obtained for p-type than for n-type doping. The variation of the thermopower as a function of temperature and concentration suggests that CuSbS$_2$ will be a good thermoelectric material at low temperatures, similarly to the isostructural CuBiS$_2$ compound.

Published
2014

36. Phase Stability and Thermoelectric Properties of the Mineral FeS2: An Ab Initio Study

Author

Gudelli, Vijay Kumar, Kanchana, V., Appalakondaiah, S., Vaitheeswaran, G., and Valsakumar, M. C.

Subjects
Condensed Matter - Materials Science
Abstract

First principles calculations were carried out to study the phase stability and thermoelectric properties of the naturally occurring marcasite phase of FeS$_2$ at ambient condition as well as under pressure. Two distinct density functional approaches has been used to investigate the above mentioned properties. The plane wave pseudopotential approach was used to study the phase stability and structural, elastic, and vibrational properties. The full potential linear augment plane wave method has been used to study the electronic structure and thermoelectric properties. From the total energy calculations, it is clearly seen that marcasite FeS$_2$ is stable at ambient conditions, and it undergoes a first order phase transition to pyrite FeS$_2$ at around 3.7 GPa with a volume collapse of about 3$\%$. The calculated ground state properties such as lattice parameters, bond lengths and bulk modulus of marcasite FeS$_2$ agree quite well with the experiment. Apart from the above studies, phonon dispersion curves unambiguously indicate that marcasite phase is stable under ambient conditions. Further, we do not observe any phonon softening across the marcasite to pyrite transition and the possible reason driving the transition is also analyzed in the present study, which has not been attempted earlier. In addition, we have also calculated the electronic structure and thermoelectric properties of the both marcasite and pyrite FeS$_2$. We find a high thermopower for both the phases, especially with p-type doping, which enables us to predict that FeS$_2$ might find promising applications as good thermoelectric materials., Comment: 10 Figures

Published
2013
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37. Electronic topological transition in LaSn$_3$ under pressure

Author

Ram, Swetarekha, Kanchana, V., Vaitheeswaran, G., Svane, A., Dugdale, S. B., and Christensen, N. E.

Subjects
Condensed Matter - Materials Science
Abstract

The electronic structure, Fermi surface and elastic properties of the iso-structural and iso-electronic LaSn$_3$ and YSn$_3$ intermetallic compounds are studied under pressure within the framework of density functional theory including spin-orbit coupling. The LaSn$_3$ Fermi surface consists of two sheets, of which the second is very complex. Under pressure a third sheet appears around compression $V/V_0=0.94$, while a small topology change in the second sheet is seen at compression $V/V_0=0.90$. This may be in accordance with the anomalous behaviour in the superconducting transition temperature observed in LaSn$_3$, which has been suggested to reflect a Fermi surface topological transition, along with a non-monotonic pressure dependence of the density of states at the Fermi level. The same behavior is not observed in YSn$_3$, the Fermi surface of which already includes three sheets at ambient conditions, and the topology remains unchanged under pressure. The reason for the difference in behaviour between LaSn$_3$ and YSn$_3$ is the role of spin-orbit coupling and the hybridization of La - $4f$ states with the Sn - $p$ states in the vicinity of the Fermi level, which is well explained using the band structure calculation. The elastic constants and related mechanical properties are calculated at ambient as well as at elevated pressures. The elastic constants increase with pressure for both compounds and satisfy the conditions for mechanical stability under pressure., Comment: 17 Figures

Published
2013
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38. Interplay of electron correlation and covalency in FeTe(0.6)Se(0.4)

Author

Adhikary, Ganesh, Biswas, Deepnarayan, Sahadev, Nishaina, Ram, Swetarekha, Kanchana, V., Yadav, C. S., Paulose, P. L., and Maiti, Kalobaran

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

We investigate the electronic structure of FeTe(0.6)Se(0.4) employing high resolution photoemission spectroscopy and ab initio band structure calculations. Fe 2p core level and the valence band spectra exhibit signature of strong electron correlation in the electronic structure. The electronic states near the Fermi level reduces in intensity with the decrease in temperature in conformity with the insulating transport observed near 300 K. The observation of an insulator to metal transition around 150 K in the transport properties may be related to the spectral lineshape change in the vicinity of the Fermi level observed in this study. The spectral features near Fermi level exhibit significant p orbital character due to the correlation induced Fe d spectral weight transfer. The experimental spectra reveal dominant temperature dependence of the spectral functions possessing large p-character. These results demonstrate significant renormalization of the character of the conduction electrons due to electron correlation and emphasizes the importance of ligand states in the superconductivity of these materials.

Published
2013
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39. Magnetism in Re-based ferrimagnetic double perovskites

Author

Winkler, A., Narayanan, N., Mikhailova, D., Bramnik, K. G., Ehrenberg, H., Fuess, H., Vaitheeswaran, G., Kanchana, V., Wilhelm, F., Rogalev, A., Kolchinskaya, A., and Alff, L.

Subjects
Condensed Matter - Materials Science, Condensed Matter - Strongly Correlated Electrons
Abstract

We have investigated spin and orbital magnetic moments of the Re 5d ion in the double perovskites A2FeReO6 (A = Ba, Sr, Ca) by X-ray magnetic circular dichroism (XMCD) at the Re L(2,3) edges. In these ferrimagnetic compounds an unusually large negative spin and positive orbital magnetic moment at the Re atoms was detected. The presence of a finite spin magnetic moment in a 'non-magnetic' double perovskite as observed in the double perovskite Sr2ScReO6 proves that Re has also a small, but finite intrinsic magnetic moment. We further show for the examples of Ba and Ca that the usually neglected alkaline earth ions undoubtedly also contribute to the magnetism in the ferrimagnetic double perovskites.

Published
2009
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40. High pressure structural study of fluoro perovskite CsCdF3 upto 60 GPa: A combined experimental and theoretical study

Author

Vaitheeswaran, G., Kanchana, V., Kumar, Ravhi. S., Cornelius, A. L., Nicol, M. F., Svane, A., Christensen, N. E., and Eriksson, O.

Subjects
Condensed Matter - Materials Science
Abstract

The structural behaviour of CsCdF3 under pressure is investigated by means of theory and experiment. High-pressure powder x-ray diffraction experiments were performed up to a maximum pressure of 60 GPa using synchrotron radiation. The cubic $Pm\bar{3}m$ crystal symmetry persists throughout this pressure range. Theoretical calculations were carried out using the full-potential linear muffin-tin orbital method within the local density approximation and the generalized gradient approximation for exchange and correlation effects. The calculated ground state properties -- the equilibrium lattice constant, bulk modulus and elastic constants -- are in good agreement with experimental results. Under ambient conditions, CsCdF3 is an indirect gap insulator with the gap increasing under pressure.

Published
2009
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41. Density functional study of elastic and vibrational properties of the Heusler-type alloys Fe$_2$VAl and Fe$_2$VGa

Author

Kanchana, V., Vaitheeswaran, G., Ma, Yanming, Xie, Yu, Svane, A., and Eriksson, O.

Subjects
Condensed Matter - Materials Science
Abstract

The structural and elastic properties as well as phonon-dispersion relations of the Heusler-type alloys Fe$_2$VAl and Fe$_2$VGa are computed using density-functional and density-functional perturbation theory within the generalized-gradient approximation. The calculated equilibrium lattice constants agree well with the experimental values. The elastic constants of Fe$_2$VAl and Fe$_2$VGa are predicted for the first time. From the elastic constants the shear modulus, Young's modulus, Poisson's ratio, sound velocities and Debye temperatures are obtained. By analyzing the ratio between the bulk and shear modulii, we conclude that both Fe$_2$VAl and Fe$_2$VGa are brittle in nature. The computed phonon-dispersion relation shows that both compounds are dynamically stable in the L1$_2$ structure without any imaginary phonon frequencies. The isomer shifts of Fe in the two compounds are discussed in terms of the Fe s partial density of states, which reveal larger ionicity/less hybridization in Fe$_2$VGa than in Fe$_2$VAl. For the same reason the Cauchy pressure is negative in Fe$_2$VAl but positive in Fe$_2$VGa, Comment: 14 pages, 3 figures

Published
2009
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45. Magnetic and Thermoelectric Properties of Mn2CoGe and Mn2CoSb.

Author

Sahoo, Sushree Sarita, Raj Natarajan, Arul, and Kanchana, V.

Subjects
THERMOELECTRIC materials, MAGNETIC properties, THERMAL conductivity, SEEBECK coefficient, DENSITY of states
Abstract

Heusler compounds stand as a versatile class of intermetallics with extraordinary electrical, magnetic, and thermoelectric properties that render them indispensable in various applications. This study delves deeply into the mechanical, dynamical, electronic, magnetic, and transport characteristics of Mn 2 CoGe and Mn 2 CoSb compounds. Both compounds display mechanical stability, ionic bonding, and a ductile nature. The positive phonon frequencies further affirm their dynamical stability. Moving to the electronic structure calculations, our assessments encompass magnetic moment, band structure, and density of states, highlighting the distinctive half-metallic characteristics inherent in these compounds. Transport coefficient calculations for both spin channels demonstrate the compounds' relative constancy in terms of Seebeck coefficient and electrical conductivity despite temperature fluctuations. The observed spin polarisation and thermoelectric response underscore the promising suitability of these compounds for future applications in spintronics and thermoelectrics. While the achieved maximum thermoelectric figure of merit value of 0.2 holds potential for their thermoelectric capabilities, further experimental validations are imperative for a comprehensive evaluation. [ABSTRACT FROM AUTHOR]

Published
2024
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48. Sr2CrOsO6: Endpoint of a spin polarized metal-insulator transition by 5d band filling

Author

Krockenberger, Y., Mogare, K., Reehuis, M., Tovar, M., Jansen, M., Vaitheeswaran, G., Kanchana, V., Bultmark, F., Delin, A., Wilhelm, F., Rogalev, A., Winkler, A., and Alff, L.

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science
Abstract

In the search for new spintronic materials with high spin-polarization at room-temperature, we have synthesized an osmium based double perovskite with a Curie-temperature of 725 K. Our combined experimental results confirm the existence of a sizable induced magnetic moment at the Os site, supported by band-structure calculations in agreement with a proposed kinetic energy driven mechanism of ferrimagnetism in these compounds. The intriguing property of Sr2CrOsO6 is that it is at the endpoint of a metal-insulator transition due to 5d band filling, and at the same time ferrimagnetism and high-spin polarization is preserved., Comment: including corrected table 1

Published
2007
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49. High-pressure structural, elastic and electronic properties of the scintillator host material, KMgF_3

Author

Vaitheeswaran, G., Kanchana, V., Kumar, R. S., Cornelius, A. L., Nicol, M. F., Svane, A., Delin, A., and Johansson, B.

Subjects
Condensed Matter - Materials Science
Abstract

The high-pressure structural behaviour of the fluoroperovskite KMgF_3 is investigated by theory and experiment. Density functional calculations were performed within the local density approximation and the generalized gradient approximation for exchange and correlation effects, as implemented within the full-potential linear muffin-tin orbital method. In situ high-pressure powder x-ray diffraction experiments were performed up to a maximum pressure of 40 GPa using synchrotron radiation. We find that the cubic Pm\bar{3}m crystal symmetry persists throughout the pressure range studied. The calculated ground state properties -- the equilibrium lattice constant, bulk modulus and elastic constants -- are in good agreement with experimental results. By analyzing the ratio between the bulk and shear modulii, we conclude that KMgF_3 is brittle in nature. Under ambient conditions, KMgF_3 is found to be an indirect gap insulator with the gap increasing under pressure., Comment: 4 figures

Published
2007
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50. Elastic constants and high-pressure structural transitions in lanthanum monochalcogenides from experiment and theory

Author

Vaitheeswaran, G., Kanchana, V., Heathman, S., Idiri, M., Bihan, T. Le, Svane, A., Delin, A., and Johansson, B.

Subjects
Condensed Matter - Materials Science
Abstract

The high-pressure structural behavior of lanthanum monochalcogenides is investigated by theory and experiment. Theory comprises density functional calculations of LaS, LaSe and LaTe with the general gradient approximation for exchange and correlation effects, as implemented within the full-potential linear muffin-tin orbital method. The experimental studies consist of high-pressure angle dispersive x-ray diffraction investigations of LaS and LaSe up to a maximum pressure of 41 GPa. A structural phase transition from the NaCl type to CsCl type crystal structure is found to occur in all cases. The experimental transition pressures are 27-28 GPa and 19 GPa, for LaS and LaSe, respectively, while the calculated transition pressures are 29 GPa, 21 GPa and 10 GPa for LaS, LaSe and LaTe, respectively. The calculated ground state properties such as equilibrium lattice constant, bulk modulus and its pressure derivative, and Debye temperatures are in good agreement with experimental results. Elastic constants are predicted from the calculations., Comment: Phys. Rev. B 75, 184108 (2007)

Published
2007
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