Magnetic structure and magnetocalorics of<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML"><mml:msub><mml:mi>GdPO</mml:mi><mml:mn>4</mml:mn></mml:msub></mml:math>

Palacios, E.; Rodríguez-Velamazán, J. A.; Evangelisti, Marco; McIntyre, Garry J.; Lorusso, Giulia; Visser, D.; Jongh, L.J. de; Boatner, L. A.

doi:10.1103/physrevb.90.214423

Cited by 103 publications

(72 citation statements)

References 24 publications

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“…Third, the exchange interaction between 3d ions, usually much higher than the R-R exchange interaction, provides an internal field, increasing the polarization of the R ions below the ferromagnetic ordering temperature. The Cr 5+ ion plays an important role as the promoter of the interactions in the rare-earth sublattice, increasing its ordering temperatures at least one order of magnitude in comparison with the analogous RXO 4 (X = P, As, V), where X is a diamagnetic element [24,25]. The case R = Gd is easier to analyze because, for this spin-only atom, the anisotropy and crystal-field energies are of the order of 1 K or less [24], therefore, a higher MCE is expected.…”

Section: Introductionmentioning

confidence: 99%

Effect of Gd polarization on the large magnetocaloric effect ofGdCrO4in a broad temperature range

et al. 2016

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The ferromagnetic zircon-type phase of GdCrO 4 presents high values for the magnetocaloric (MC) parameters. This compound has large isothermal entropy changes S T under the magnetic field action in a wide temperature range, from 5 to 35 K, reaching a maximum | S T | = 29.0 ± 0.1 J/kg K at 22 K, for a field increment B = 9 T. It orders ferromagnetically at T C = 21.3 K via the Cr-Cr exchange interaction and shows a second transition at 4.8 K due to the ordering of the Gd sublattice. The large MC effect is enhanced by the polarization of the Gd 3+ ions by the Cr 5+ ones via a weaker Gd-Cr interaction. This effect is an interesting feature to be considered in the search for new compounds with a high MC effect in the range of liquid hydrogen or natural gas, regarding the liquefaction of gases by magnetization-demagnetization cycles. This paper contains experimental measurements of magnetization, heat capacity, and direct determinations of the MC effect. The magnetic contribution to the heat capacity C m has been obtained after subtracting the lattice component. Approximate values for the exchange constants J 1 (Cr-Cr) and J 3 (Gd-Cr) have been deduced from C m .

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Section: Introductionmentioning

confidence: 99%

Effect of Gd polarization on the large magnetocaloric effect ofGdCrO4in a broad temperature range

et al. 2016

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“…On the other hand, several compounds and intermetallic alloys, such as Ho 5 Pd 2 , DyAl 2 , HoCo 2 , ErCo 2 , HoNiSi, HoRu 2 Si 2 , and GdPO 4 , have been reported to show large MCE at low temperature and are therefore promising for cryogenic magnetic refrigeration. [1][2][3][4][5] It should be noted that these intermetallic alloys possess a relatively low resistivity, thus causing huge eddy current losses when used in actual magnetic cooling devices. Some also exhibit considerable thermal and magnetic hysteresis losses which are undesirable for active magnetic refrigeration.…”

Section: Introductionmentioning

confidence: 99%

“…[1][2][3][4][5][6] One major emphasis for the research in this area is to find refrigerant materials exhibiting a large MCE in different temperature regimes, from room temperature to cryogenic temperatures. Two distinct temperature ranges of practical interests are near room temperature and below liquid nitrogen temperature (the so-called cryogenic temperature range).…”

Section: Introductionmentioning

confidence: 99%

Enhanced cryogenic magnetocaloric effect in Eu8Ga16Ge30 clathrate nanocrystals

Biswas

Chandra

Stefanoski

et al. 2015

Journal of Applied Physics

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Articles you may be interested inLarge magnetocaloric effects over a wide temperature range in MnCo1−xZnxGe J. Appl. Phys. 113, 17A922 (2013); 10.1063/1.4798339 We observe an enhanced magnetic entropy change (ÀDS M ) at cryogenic temperatures (T < 20 K) in Eu 8 Ga 16 Ge 30 clathrate (type-I) nanocrystals prepared by a ball milling method. With reduction in the crystal size to 15 nm, ÀDS M is enhanced at low temperatures, reaching the highest value ($10 J/kg K) at 5 K for a field change of 5 T. For all samples investigated, there is a cross-over temperature ($25 K) in ÀDS M (T) above which ÀDS M decreases with crystal size, opposite to that observed at low temperatures. A careful analysis of the magnetic and magnetocaloric data reveals that as the crystal size decreases the magnetic interaction between Eu 2þ ions on the Eu2 site governing the primary ferromagnetic transition at $35 K becomes gradually weaker, in effect, altering the interaction between Eu 2þ ions occupying the Eu1 and Eu2 sites responsible for the secondary ferromagnetic transition at 15 K. As a result, we have observed a strong change in magnetization and the enhancement of ÀDS M at low temperature. V C 2015 AIP Publishing LLC.

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“…[13] Of these, gadolinium gallium garnet (GGG), which shows no long-range ordering down to 25 mK, has been established as a MCM for magnetic refrigeration in the liquid helium temperature regime. The absence of long-range ordering, high density of magnetic ions, chemical stability, and lack of single ion anisotropy (L = 0 for Gd 3+ ) allowing for the full magnetic entropy (Rln[2J + 1] = 17.29 J K −1 mol Gd −1 ) to be extracted in high magnetic fields makes it an ideal MCM for T < 20 K. [14][15][16] In recent years, a number of Gd containing MCMs with better performance at 2 K have been reported [17][18][19][20] but GGG continues to be used and serves as the benchmark for MCMs in this temperature regime. However, for all the Gd-based magnetocalorics, the change in magnetic entropy is maximized in fields of 5 T or higher.…”

mentioning

confidence: 99%

“…) to be extracted in high magnetic fields makes it an ideal MCM for T < 20 K. [14][15][16] In recent years, a number of Gd containing MCMs with better performance at 2 K have been reported [17][18][19][20] but GGG continues to be used and serves as the benchmark for MCMs in this temperature regime. However, for all the Gd-based magnetocalorics, the change in magnetic entropy is maximized in fields of 5 T or higher.…”

mentioning

confidence: 99%

Enhanced Magnetocaloric Effect from Cr Substitution in Ising Lanthanide Gallium Garnets Ln₃CrGa₄O₁₂ (Ln = Tb, Dy, Ho)

Mukherjee

Dutton

2017

Adv Funct Materials

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A detailed study on the crystal structure and bulk magnetic properties of Cr substituted Ising type lanthanide gallium garnets Ln 3 CrGa 4 O 12 (Ln = Tb, Dy, Ho) is carried out using room temperature powder X-ray and neutron diffraction, magnetic susceptibility, isothermal magnetization, and heat capacity measurements. The magnetocaloric effect (MCE) where the geometry of the magnetic lattice prevents all the nearest-neighbor magnetic interactions from being satisfied simultaneously. [8] This suppresses or in some cases, completely inhibits magnetic longrange ordering. Geometrically frustrated magnets (GFMs) typically show ordering features at T 0 ∼ θ CW /10 where θ CW is the Curie-Weiss temperature, thereby suppressing the ordering temperature. [9] In complex lanthanide oxides, the highly localized 4f orbitals have weak magnetic interactions, i.e., θ CW is small and so when the magnetic lattice is frustrated, ordering is suppressed to even lower T. The theoretical magnetic entropy that can be extracted is much higher than in transition metal compounds. GFMs with Ln 3+ ions are therefore ideal candidates for sub 20 K magnetocaloric materials (MCMs). Another advantage is that the lanthanides are chemically very similar but their magnetic properties vary widely. This allows tuning of the properties for optimization of the MCE. [10][11][12] The lanthanide gallium garnets, Ln 3 Ga 5 O 12, are a family of materials, where the magnetic Ln 3+ spins form two interpenetrating networks of ten membered-rings of corner-sharing triangles leading to a high degree of geometrical frustration. [13] Of these, gadolinium gallium garnet (GGG), which shows no long-range ordering down to 25 mK, has been established as a MCM for magnetic refrigeration in the liquid helium temperature regime. The absence of long-range ordering, high density of magnetic ions, chemical stability, and lack of single ion anisotropy (L = 0 for Gd 3+ ) allowing for the full magnetic entropy) to be extracted in high magnetic fields makes it an ideal MCM for T < 20 K. [14][15][16] In recent years, a number of Gd containing MCMs with better performance at 2 K have been reported [17][18][19][20] but GGG continues to be used and serves as the benchmark for MCMs in this temperature regime. However, for all the Gd-based magnetocalorics, the change in magnetic entropy is maximized in fields of 5 T or higher. Such high magnetic fields can only be produced using a superconducting magnet which again requires cooling using cryogens. For more practical applications, we need to focus on developing materials with high MCE in fields ≤ 2 T, attainable by a permanent magnet. This has been discussed in a recent study on Tb(HCO 2 ) 3 where the MCE is significantly higher than Gd(HCO 2 ) 3 at higher temperatures and lower fields as the Tb 3+ have Ising-like spins contrasted with the Heisenberg nature of the Gd 3+ spins. [21] For Ln 3 Ga 5 O 12 , the MCE in fields ≤2 T is expected to be maximized for the Ln 3+ having Ising-like spins, Magnetic Materials

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Magnetic structure and magnetocalorics ofGdPO4

Cited by 103 publications

References 24 publications

Effect of Gd polarization on the large magnetocaloric effect ofGdCrO4in a broad temperature range

Effect of Gd polarization on the large magnetocaloric effect ofGdCrO4in a broad temperature range

Enhanced cryogenic magnetocaloric effect in Eu8Ga16Ge30 clathrate nanocrystals

Enhanced Magnetocaloric Effect from Cr Substitution in Ising Lanthanide Gallium Garnets Ln₃CrGa₄O₁₂ (Ln = Tb, Dy, Ho)

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Magnetic structure and magnetocalorics ofGdPO4

Cited by 103 publications

References 24 publications

Effect of Gd polarization on the large magnetocaloric effect ofGdCrO4in a broad temperature range

Effect of Gd polarization on the large magnetocaloric effect ofGdCrO4in a broad temperature range

Enhanced cryogenic magnetocaloric effect in Eu8Ga16Ge30 clathrate nanocrystals

Enhanced Magnetocaloric Effect from Cr Substitution in Ising Lanthanide Gallium Garnets Ln3CrGa4O12 (Ln = Tb, Dy, Ho)

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Enhanced Magnetocaloric Effect from Cr Substitution in Ising Lanthanide Gallium Garnets Ln₃CrGa₄O₁₂ (Ln = Tb, Dy, Ho)