Electronic topological transition and noncollinear magnetism in compressed hcp Co

Kvashnin, Yaroslav; Sun, Wei; Marco, Igor Di; Eriksson, Olle

doi:10.1103/physrevb.92.134422

Cited by 21 publications

(15 citation statements)

References 45 publications

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“…The Curie temperatures for both HCP (T c = 1250 K) and FCC (T c = 1300 K) phases calculated with our parameters are also close to the experimental one (see Table I) although they are below it. At the same time the calculations by Kvashnin et al [26]) give a smaller Curie temperature T C = 1100 K but in agreement with the value of 1131 K cited in the book by Cullity [43]. We note that our estimations of T c do not include the effects of longitudinal spin fluctuations at high temperatures and renormalization of the exchange constants due to the spin disorder in a paramagnetic state [35].…”

Section: A the Heisenberg Exchange Parameterizationsupporting

confidence: 89%

“…The exchange constants were estimated in ferromagnetic ground state at T = 0 K, which give a reasonable estimation also at non-zero temperatures for both fcc and hcp Co. Our method of the exchange constants calculation is essentially the same as that of Pajda et al [25], however, we used a more extended basis for partial wave expansion (l max = 3) than Pajda et al who used l max = 2. Because of that our exchange constants are closer to Kvashnin et al [26], who used a full potential methodology. Previously, the application of our approach has allowed a successful description of magnetism in various transition metal systems [30,31].…”

Section: A the Heisenberg Exchange Parameterizationsupporting

confidence: 69%

“…The first set of these parameters for HCP Co at T = 0 K was evaluated by Turek et al [24] and for FCC Co by Pajda et al [25] with experimental lattice parameters. Very recently a new set data has been published by Kvashnin et al [26]. Since the calculated exchange parameters in these two works are different, we have performed our own calculations of the Heisenberg exchange parameters (see Table I).…”

Section: A the Heisenberg Exchange Parameterizationmentioning

confidence: 99%

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Temperature-dependent exchange stiffness and domain wall width in Co

et al. 2016

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The micromagnetic exchange stiffness is a critical parameter in numerical modeling of magnetization dynamics and reversal processes, yet the current literature reports a wide range of values even for such simple and widely used material as Cobalt.With use of ab-intio estimated Heisenberg parameters we calculate the low temperature micromagnetic exchange stiffness parameters for hexagonal-close-packed (HCP) and face-centred cubic Cobalt without previous and our own. For HCP Co they are slightly different in the directions parallel and perpendicular to the c-axis. We establish the exchange stiffness scaling relation with magnetization A(m) ∼ m 1.8 valid for all sets of parameters for a wide range of temperatures. For HCP Co we find an anisotropic domain wall width in the range 24 − 29 nm which increases slowly with temperature. The results form a critical input for large-scale temperature-dependent micromagnetics simulations and demonstrate the importance of correct parameterization for accurate simulation of magnetization dynamics.

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Section: A the Heisenberg Exchange Parameterizationsupporting

confidence: 89%

Section: A the Heisenberg Exchange Parameterizationsupporting

confidence: 69%

Section: A the Heisenberg Exchange Parameterizationmentioning

confidence: 99%

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Temperature-dependent exchange stiffness and domain wall width in Co

et al. 2016

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“…As a matter of fact, the anomalous phenomena with compression that occurs for c/a is also present in Fe [40], Co [41], Zn [42], and Os [43], which as reported results from ETT. According to the above discussions, a perturbation on d ln(c/a)/dP appears at 10 GPa, and a drastic change takes place at 17 GPa in α Hf.…”

Section: A Structural Elastic and Vibrational Propertiessupporting

confidence: 53%

Anisotropic distortion and Lifshitz transition inα-Hf under pressure

et al. 2017

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In this work we report a theoretical investigation on behavior of the elastic constant C 44 and the transverse optical phonon mode E 2g of α-Hf under pressure within the density functional theory. In contrast to many other reported transition metals, the above two quantities do not show a synchronous relation as pressure increases. Below 13 GPa, an opposite shifting tendency has been observed. However, once the pressure is raised above 13 GPa, the trend is pulled back to be consistent. This anomalous behavior is figured out to be caused by the large lattice anisotropy of the c/a ratio along with the elastic anisotropy. The synchronous behavior is found to be in accordance with the behavior of c/a ratio with increased pressure. In our band-structure investigations the electronic topological transition has been discovered at 10 GPa, which relates to the change of c/a ratio suggested by recent literature. The presence of the Van Hove singularity shown in the densities of states has been identified and regarded as the origin of the variation of C 44 and E 2g .

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“…In the case of CsCl-type FeSe a transition from AFM phase to NM phase is observed with intermediate FM phase [32]. HCP Co is observed to become non-magnetic at a pressure of 180 Gpa with a series of electronic topological transitions (ETT) at different pressures [33].…”

Section: Notesmentioning

confidence: 98%

Evidence of ferromagnetic ground state and strong spin phonon coupling in Zr₂TiAl with bi-axial strain: first principles study

2019

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A detailed study on the inter-metallic alloy, Zr 2 TiAl, has been carried out using first principle electronic structure calculations. We found that a small value of bi-axial strain/stress cause a phase change from anti-ferromagnetic(AFM) to ferromagnetic(FM) with a structural transition from face center cubic (fcc) to body center tetragonal (bct). Calculated electronic band structures show that all strained structures are metallic in nature with Zr-d and Ti-d orbital dominated energy bands near the Fermi level(E F ). The stability of FM phase is confirmed with phonon dispersion calculations by using density functional perturbation theory (DFPT). It has been observed that AFM state with both positive and negative bi-axial stress exhibits unstable modes while corresponding FM state shows no such instability. This clearly indicates the existence of large spin phonon coupling in this material.

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Electronic topological transition and noncollinear magnetism in compressed hcp Co

Cited by 21 publications

References 45 publications

Temperature-dependent exchange stiffness and domain wall width in Co

Temperature-dependent exchange stiffness and domain wall width in Co

Anisotropic distortion and Lifshitz transition inα-Hf under pressure

Evidence of ferromagnetic ground state and strong spin phonon coupling in Zr₂TiAl with bi-axial strain: first principles study

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Electronic topological transition and noncollinear magnetism in compressed hcp Co

Cited by 21 publications

References 45 publications

Temperature-dependent exchange stiffness and domain wall width in Co

Temperature-dependent exchange stiffness and domain wall width in Co

Anisotropic distortion and Lifshitz transition inα-Hf under pressure

Evidence of ferromagnetic ground state and strong spin phonon coupling in Zr2TiAl with bi-axial strain: first principles study

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Evidence of ferromagnetic ground state and strong spin phonon coupling in Zr₂TiAl with bi-axial strain: first principles study