Enhanced cryogenic magnetocaloric effect in Eu8Ga16Ge30 clathrate nanocrystals

Biswas, Anis; Chandra, Sayan; Stefanoski, Stevce; Blázquez, J.S.; Ipus, J.J.; Conde, A.; Phan, Manh‐Huong; Franco, V.; Nolas, George S.; Srikanth, H.

doi:10.1063/1.4906280

Cited by 17 publications

(13 citation statements)

References 33 publications

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“…These results are consistent with a number of publications, e.g. 6,9,10 which show that reducing the size of nanoparticles leads to a shift of the paramagnetic to ferromagnetic phase transition towards lower temperatures and, as a consequence, the maximum of Δ S is also moved towards lower temperatures. It should be also emphasised that the reduction of the dimensionality of the bulk magnetocaloric material to a nanoscale film form can significantly change the magnetic properties of these materials and, consequently, their magnetocaloric properties.…”

Section: Resultssupporting

confidence: 93%

Magnetocaloric materials with ultra-small magnetic nanoparticles working at room temperature

Dudek

Wolak

et al. 2019

Sci Rep

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Through the use of the Monte Carlo simulations utilising the mean-field approach, we show that a dense assembly of separated ultra-small magnetic nanoparticles embedded into a non-magnetic deformable matrix can be characterized by a large isothermal magnetic entropy change even upon applying a weak magnetic field with values much smaller than one Tesla. We also show that such entropy change may be very significant in the vicinity of the room temperature which effect normally requires an application of a strong external magnetic field. The deformable matrix chosen in this work as a host for magnetic nanoparticles adopts a thin film form with a large surface area to volume ratio. This in turn in combination with a strong magneto-volume coupling exhibited by this material allows us to show its suitability to be used in the case of a variety of applications utilising local cooling/heating such as future magnetic refrigerants.

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Section: Resultssupporting

confidence: 93%

Magnetocaloric materials with ultra-small magnetic nanoparticles working at room temperature

Dudek

Wolak

et al. 2019

Sci Rep

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“…1a) and it is found to be proportional to the milling time. These results are in agreement with other studies like: Gd3Fe5O12 and Eu8Ga16Ge30 clathrate nanocrystals [34,36]. In the case of Tb5Si2Ge2, the XRD pattern remains almost unaltered demonstrating that at room temperature the stable 5:4 phase is the M phase.…”

Section: A Structural Characterizationsupporting

confidence: 92%

Influence of short time milling in R5(Si,Ge)4, R = Gd and Tb, magnetocaloric materials

et al. 2015

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The effect of the short milling times on R5(Si,Ge)4 R =Gd, Tb magnetocaloric material properties was investigated. In particular, the effect of milling on atomic structure, particles size and morphology, magnetic, and magnetocaloric effect was studied. With short milling times (< 2.5h), a reduction of the Gd5Si1.3Ge2.7 and Tb5Si2Ge2 particles size was achieved down to approximately 3.5 µm. For both compositions the main differences are a consequence of the milling effect on the coupling of the structural and magnetic transitions. In the Gd5Si1.3Ge2.7 case, a second-order phase transition emerges at high temperatures as a result of ball milling. Consequently, there is a decrease in the magnetocaloric effect of 35% after 150 minutes of milling. Interestingly, an opposite effect is observed in Tb5Si2Ge2 where a 23% increase of the magnetocaloric effect was achieved, driven by the enhancement of the coupling between magnetic and structural transitions arising from internal strain promoted by the milling process.

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“…First-order transition materials (FOTM) can show good MCE properties, but they exhibit magnetic and temperature hysteresis. In practical applications, which involve magnetic field and temperature cycling, the magnetocaloric materials should exhibit near zero magnetic and thermal hysteresis during an alternating magnetic field and temperature sweeps, respectively [Pecharsky 2006, Biswas 2015. Hysteresis diminishes the energy efficiency of the magnetocaloric device; therefore, secondorder transition materials (SOTM) are generally preferred because of their low hysteresis compared to FOTM.…”

Section: Introductionmentioning

confidence: 99%

High Relative Cooling Power in a Multiphase Magnetocaloric FeNiB Alloy

Chaudhary

Ramanujan

2015

IEEE Magn. Lett.

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Low-cost magnetic cooling based on the magnetocaloric effect is an energy efficient, environmentally friendly, thermal management technology. However, inadequate temperature span is often a challenge in developing a magnetic cooling system. We report the novel use of multiphase materials to enhance the working temperature span (δT FWHM ) of the magnetic entropy change and the relative cooling power of a Fe-Ni-B bulk alloy. The coexistence of bcc, fcc, and spinel phases results in large working temperature spans of 322.3 and 439.0 K for magnetic field change of 1 and 5 T, respectively. δT FWHM for this multiphase (Fe 70 Ni 30 ) 89 B 11 alloy is about 86% higher than the corresponding value for single-phase γ -(Fe 70 Ni 30 ) 89 B 11 alloy for H = 1 T. These values are the largest for any bulk magnetocaloric material and even higher than most magnetocaloric nanoparticles. The relative cooling power is also higher than comparable materials, including the benchmark magnetocaloric material, gadolinium.Index Terms-Current topics, coupled phenomena, iron alloy, magnetocaloric effect, relative cooling power.1949-307X C 2015 IEEE. Personal use is permitted, but republication/redistribution requires IEEE permission.See http://www.ieee.org/publications_standards/publications/rights/index.html for more information.

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Enhanced cryogenic magnetocaloric effect in Eu8Ga16Ge30 clathrate nanocrystals

Cited by 17 publications

References 33 publications

Magnetocaloric materials with ultra-small magnetic nanoparticles working at room temperature

Magnetocaloric materials with ultra-small magnetic nanoparticles working at room temperature

Influence of short time milling in R5(Si,Ge)4, R = Gd and Tb, magnetocaloric materials

High Relative Cooling Power in a Multiphase Magnetocaloric FeNiB Alloy

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