Impact of lattice dynamics on the phase stability of metamagnetic FeRh: Bulk and thin films

Wolloch, Michael; Gruner, Markus E.; Keune, W.; Mohn, P.; Redinger, Josef; Hofer, Ferdinand; Suess, Dieter; Podloucky, R.; Landers, Joachim; Salamon, Soma; Scheibel, Franziska; Spoddig, D.; Witte, Ralf; Cuenya, Beatriz Roldán; Gutfleisch, Oliver; Hu, Michael Y.; Zhao, Jiyong; Toellner, T. S.; E., E.; Siewert, Mario; Entel, P.; Pentcheva, Rossitza; Wende, Heiko

doi:10.1103/physrevb.94.174435

Cited by 50 publications

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References 121 publications

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“…Both properties may change at a magnetostructural transition. This is expressed quantitatively in terms of the vibrational density of states (VDOS) g ( ϵ ), which can be measured by inelastic neutron scattering or nuclear resonant inelastic X‐ray scattering . VDOS and phonon dispersion relations have been calculated from first principles achieving excellent agreement with experimental data .…”

Section: Disentangling the Microscopic Contributions To The Entropy Cmentioning

confidence: 89%

“…This is expressed quantitatively in terms of the vibrational density of states (VDOS) g ( ϵ ), which can be measured by inelastic neutron scattering or nuclear resonant inelastic X‐ray scattering . VDOS and phonon dispersion relations have been calculated from first principles achieving excellent agreement with experimental data . The expression for S lat resembles S el , where the expression in the parentheses takes into account the Bosonic character of the phonons through the Bose–Einstein distribution function n ( ϵ , T )=(exp( ϵ / k B T )−1) −1 for the occupation numbers, which becomes large for high T or small phonon energies ϵ :

true S_{normall normala normalt} = 3 k_{B} \int_{0}^{\infty} g ((), ϵ) [(1 + n (() ϵ, T)) l n (1 + n (() ϵ, T)) - n (ϵ, T) l n (n (() ϵ, T))] normald ϵ

…”

Section: Disentangling the Microscopic Contributions To The Entropy Cmentioning

confidence: 94%

“…Thus, we can expect considerable contributions from S el to the magnetocaloric effect if strong features in the DOS right at

E_{F}

appear or disappear during a magnetostructural transition. This is for instance the case for La(Fe x Si 1− x ) 13 or FeRh . For second‐order transitions, S el can be considered to be unimportant.…”

Section: Disentangling the Microscopic Contributions To The Entropy Cmentioning

confidence: 99%

“…As we will discuss below, the three contributions to Δ S can have the same sign. This is the case for the magnetocaloric systems La(Fe x Si 1− x ) 13 and FeRh . However, one strictly cannot assume that the degrees of freedom are totally independent.…”

Section: Disentangling the Microscopic Contributions To The Entropy Cmentioning

confidence: 99%

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Hysteresis Design of Magnetocaloric Materials—From Basic Mechanisms to Applications

et al. 2018

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Magnetic refrigeration relies on a substantial entropy change in a magnetocaloric material when a magnetic field is applied. Such entropy changes are present at first‐order magnetostructural transitions around a specific temperature at which the applied magnetic field induces a magnetostructural phase transition and causes a conventional or inverse magnetocaloric effect (MCE). First‐order magnetostructural transitions show large effects, but involve transitional hysteresis, which is a loss source that hinders the reversibility of the adiabatic temperature change ΔTad. However, reversibility is required for the efficient operation of the heat pump. Thus, it is the mastering of that hysteresis that is the key challenge to advance magnetocaloric materials. We review the origin of the large MCE and of the hysteresis in the most promising first‐order magnetocaloric materials such as Ni–Mn‐based Heusler alloys, FeRh, La(FeSi)13‐based compounds, Mn3GaC antiperovskites, and Fe2P compounds. We discuss the microscopic contributions of the entropy change, the magnetic interactions, the effect of hysteresis on the reversible MCE, and the size‐ and time‐dependence of the MCE at magnetostructural transitions.

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Section: Disentangling the Microscopic Contributions To The Entropy Cmentioning

confidence: 89%

true S_{normall normala normalt} = 3 k_{B} \int_{0}^{\infty} g ((), ϵ) [(1 + n (() ϵ, T)) l n (1 + n (() ϵ, T)) - n (ϵ, T) l n (n (() ϵ, T))] normald ϵ

…”

Section: Disentangling the Microscopic Contributions To The Entropy Cmentioning

confidence: 94%

“…Thus, we can expect considerable contributions from S el to the magnetocaloric effect if strong features in the DOS right at

E_{F}

Section: Disentangling the Microscopic Contributions To The Entropy Cmentioning

confidence: 99%

Section: Disentangling the Microscopic Contributions To The Entropy Cmentioning

confidence: 99%

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Hysteresis Design of Magnetocaloric Materials—From Basic Mechanisms to Applications

et al. 2018

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“…It has been shown that a magnetic state change of Rh between antiferromagnetism (with a Rh moment of 0 μ B ) and ferromagnetism (≈0.9 μ B ), accompanied by a significant change in electronic structure, combine as the main origin of the metamagnetic transition . To be more precise, it is the cooperative contribution of electronic, magnetic, and vibrational degrees of freedom that is responsible for the giant magnetocaloric effect in FeRh . The alloy Ni 45 Co 5 Mn 32 Cr 5 In 13 is stable with respect to decomposition into all individual elements.…”

Section: Magnetostructural Phase Transition Of Rapidly Quenched Heuslmentioning

confidence: 99%

Properties and Decomposition of Heusler Alloys

et al. 2018

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Martensitic transformations of rapidly quenched and less‐rapidly cooled Heusler alloys of type Ni–Mn–X with X=Ga, In, and Sn are investigated by ab initio calculations. For alloys rapidly cooled from 1173 K, we obtain the well‐known magnetocaloric properties near the magnetocaloric phase transition. For the less‐rapidly cooled alloys with secondary heat treatment these magnetocaloric properties start to change considerably, because each alloy transforms during temper‐annealing into a dual‐phase composite alloy. These two phases are identified to be cubic stoichiometric Ni2MnX and tetragonal disordered NiMn.

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Local Photothermal Control of Phase Transitions for On‐Demand Room‐Temperature Rewritable Magnetic Patterning

et al. 2020

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The ability to make controlled patterns of magnetic structures within a nonmagnetic background is essential for several types of existing and proposed technologies. Such patterns provide the foundation of magnetic memory and logic devices 1 , allow the creation of artificial spinice lattices 2,3 and enable the study of magnon propagation 4 . Here, we report a novel approach for magnetic patterning that allows repeated creation and erasure of arbitrary shapes of thin-film ferromagnetic structures. This strategy is enabled by epitaxial Fe 0.52 Rh 0.48 thin films designed so that both ferromagnetic and antiferromagnetic phases are bistable at room temperature. Starting with the film in a uniform antiferromagnetic state, we demonstrate the ability to write arbitrary patterns of the ferromagnetic phase by local heating with a focused laser. If desired, the results can then be erased by cooling with a thermoelectric cooler and the material repeatedly repatterned.Intermetallic Fe 1-x Rh x (B2, P m3m) exhibits a hysteretic antiferromagnetic/ferromagnetic transformation which has been harnessed to produce composite multiferroics exhibiting record-breaking magnetoelectric coupling coefficients 5 , magnetocaloric refrigerators with competitive cooling capabilities 6 and novel memories based on antiferromagnetic order 7 . In this study, we design epitaxial Fe 1-x Rh x films so that both ferromagnetic and antiferromagnetic states are simultaneously bistable at room temperature. We engineer the width of the thermal hysteresis to be sufficiently narrow to enable efficient controllability, but also wide enough to robustly withstand thermal perturbations. Moderate heating by a focused laser is used to locally drive antiferromagnetic regions controllably to the ferromagnetic phase, demonstrating the patterning of arbitrary magnetic features on the submicron scale. These findings present opportunities for writing and erasing high-fidelity magnetically active nanostructures that are of interest for magnonic crystals 8 , artificial spin-ice lattices 9 and memory 10 and logic devices 11 . FIG. 1.Fully-dense phase-pure untwinned epitaxial B2 Fe0.52Rh0.48/MgO(001) layers grown via molecular-beam epitaxy. a, RBS spectrum; labeled iron and rhodium spectral features correspond to a magnetically bistable rhodium fraction of 0.48. b, BF-TEM image of the entire film cross section together with c, a corresponding SAED pattern. Note the weaker film and more intense substrate reflections. d, XRD θ-2θ scan; film (violet) and substrate (orange) reflections are indexed. e, XRD ω-rocking scan about the 001 film peak.Fe 1-x Rh x films are grown epitaxially on singlecrystalline (001)-oriented MgO substrates using molecular-beam epitaxy. The fraction x of rhodium in the film is carefully tuned to 0.48, where the hysteretic antiferromagnet/ferromagnet phase transitions are centered near room temperature. Film compositions are confirmed via Rutherford backscattering spectrometry (RBS) measurements (Fig. 1a) using the areal ratio of corresponding iron and...

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Impact of lattice dynamics on the phase stability of metamagnetic FeRh: Bulk and thin films

Cited by 50 publications

References 121 publications

Hysteresis Design of Magnetocaloric Materials—From Basic Mechanisms to Applications

Hysteresis Design of Magnetocaloric Materials—From Basic Mechanisms to Applications

Properties and Decomposition of Heusler Alloys

Local Photothermal Control of Phase Transitions for On‐Demand Room‐Temperature Rewritable Magnetic Patterning

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