Your search keyword '"Zhang, Yikun"' showing total 14 results

1. Magnetic properties, magnetocaloric effect and refrigeration performance in RE60Al20Ni20 (RE = Tm, Er and Ho) amorphous ribbons.

Author

Zhang, Yikun, Guo, Dan, Wu, Bingbing, Wang, Haifeng, Guan, Renguo, Li, Xi, and Ren, Zhongming

Subjects

*MAGNETIC properties, *MAGNETOCALORIC effects, *MAGNETIC transitions, *MAGNETIC cooling, *MANGANESE alloys, *MAGNETIC fields, *THULIUM

Abstract

Rare-earth based amorphous alloys with promising glass forming ability (GFA) and considerable magnetocaloric effect (MCE) are extensively exploited for magnetic refrigeration (MR) materials. Here, the GFA, magnetic properties, MCE, and refrigeration performance of RE60Al20Ni20 (RE = Tm, Er, and Ho) amorphous ribbons were investigated. A magnetic phase transition (paramagnetic to ferromagnetic, second-order) with ignorable field and thermal hysteresis was found around TC ∼ 4.4 K for Tm60Al20Ni20, ∼9.5 K for Er60Al20Ni20, and ∼17.9 K for Ho60Al20Ni20. For a field change ΔH = 50 kOe, the MCE parameters of the maximal magnetic entropy change (around their own TC) and relative cooling power are 14.1 J/kg K and 235 J/kg for Tm60Al20Ni20, 14.3 J/kg K and 372 J/kg for Er60Al20Ni20, and 12.4 J/kg K and 460 J/kg for Ho60Al20Ni20. In addition, the temperature averaged entropy change at ΔTlift (temperature span) of 2 K and 5 K is investigated, very close values and similar field dependence with magnetic entropy change indicating that RE60Al20Ni20 (RE = Tm, Er, and Ho) has potential applications in cryogenic magnetic refrigeration. [ABSTRACT FROM AUTHOR]

Published

2020

2. Investigation of the structural and magnetic properties of the GdCoC compound featuring excellent cryogenic magnetocaloric performance.

Author

Zhang, Yikun, Hao, Weixiang, Shen, Jun, Mo, Zhaojun, Gottschall, Tino, and Li, Lingwei

Subjects

*MAGNETIC properties, *MAGNETIC transitions, *CRYOGENICS, *MAGNETIC cooling, *MAGNETIC entropy, *MAGNETOCALORIC effects, *MAGNETIC fields

Abstract

Magnetic refrigeration (MR) based on the magnetocaloric effect (MCE) has been recognized as an environmentally benign and energy-efficient cooling technology. Exploring suitable magnetocaloric materials is a crucial prerequisite for practical MR applications. We have herein provided a systematic investigation of the crystal structure, microstructure, electronic structure, magnetic phase transition, critical behavior, and MCE of the GdCoC compound featuring excellent cryogenic magnetocaloric performance by means of experimental determination and theoretical calculation. The GdCoC compound is crystallized in a simple layered tetragonal crystal structure with a P 4 2 / mmc space group and undergoes two successive ferromagnetic (FM) transitions along with a low-temperature weak antiferromagnetic (AFM) transition under low magnetic fields. Density functional theory calculations confirms the FM coupling of the Gd and Co intra-sublattice interactions, whereas AFM coupling for their inter-sublattice interaction. The magnetic transitions are merged in to one under high magnetic fields which has been confirmed to be second-order type and its critical behavior can be understood in the framework of tri-critical mean-field model, whereas the low-temperature weak AFM transition is belonging to the first-order type. The excellent magnetocaloric performance of the GdCoC compound was identified by the parameters of magnetic entropy change, adiabatic temperature change, temperature-averaged entropy change, relative cooling power, and refrigerant capacity, which are superior to most of the well-known magnetocaloric materials with similar working temperatures, making it attractive for practical cryogenic MR applications. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

3. Cryogenic magnetic properties and magnetocaloric effects (MCE) in B-site disordered RE2CuMnO6 (RE = Gd, Dy, Ho and Er) double perovskites (DP) compounds.

Author

Zhang, Yikun, Zhang, Bin, Li, Shuo, Zhu, Jian, Wu, Bingbing, Wang, Jiang, and Ren, Zhongming

Subjects

*MAGNETOCALORIC effects, *MAGNETIC properties, *RARE earth metals, *MANGANESE alloys, *MAGNETIC transitions, *MAGNETIC entropy, *MAGNETIC fields, *SPACE groups

Abstract

In this paper, a detailed investigation with respect to the structural, cryogenic magnetic properties and magnetocaloric performances of RE 2 CuMnO 6 (RE = Gd, Dy, Ho and Er) double perovskite (DP) compounds has been performed. All the RE 2 CuMnO 6 compounds are confirmed to B -site disordered and crystallized in the GdFeO 3 -type structure (Pnma space group, N 62, oP20). The magnetic transition temperatures (T M) are found to be ~7.5 K for Gd 2 CuMnO 6 , ~12.1 K for Dy 2 CuMnO 6 , ~12.2 K for Ho 2 CuMnO 6 , and ~3.6 K for Er 2 CuMnO 6 , respectively. Moreover, for checking the magnetocaloric performances several vital parameters including -Δ S M max (peak value of magnetic entropy change, -Δ S M), TEC (3) (temperature averaged -Δ S M) and RCP (relative cooling powers) are evaluated to be 7.84, 7.73 J/kgK and 151.1 J/kg for Gd 2 CuMnO 6 , 5.69, 5.59 J/kgK and 180.9 J/kg for Dy 2 CuMnO 6 , 7.12, 7.05 J/kgK and 192.4 J/kg for Ho 2 CuMnO 6 , as well as 9.92, 9.60 J/kgK and 195.9 J/kg for Er 2 CuMnO 6 under the magnetic field change Δ H = 5 T, respectively. [ABSTRACT FROM AUTHOR]

Published

2021

4. Magnetic properties and promising cryogenic magneto-caloric performances of Gd20Ho20Tm20Cu20Ni20 amorphous ribbons.

Author

Zhang, Yikun, Wu, Bingbing, Guo, Dan, Wang, Jiang, and Ren, Zhongming

Subjects

*MAGNETOCALORIC effects, *MAGNETIC properties, *MAGNETIC cooling, *THULIUM, *MANGANESE alloys, *MAGNETIC fields, *ENERGY consumption

Abstract

The magnetic cooling utilizing magneto-caloric effect is recognized as promising energy efficiency and environmentally friendly technology. Here we report a systematical study on the microstructures, magnetic properties and cryogenic magneto-caloric performances of the Gd20Ho20Tm20Cu20Ni20 amorphous ribbons. It is found that the ribbons reveal a second-order phase transition and are accompanied by a table-shaped magneto-caloric effect. The calculated magnetic-entropy-change maximum |ΔSM|, temperature averaged entropy change (i.e., TEC(10)), and refrigerant capacity reach 13.9 J/kg⋅K, 13.84 J/kg⋅K and 740 J/kg with magnetic field change of 0–7 T, respectively, indicating that the present Gd20Ho20Tm20Cu20Ni20 amorphous ribbons are good candidates for magnetic cooling. [ABSTRACT FROM AUTHOR]

Published

2021

5. Review of the structural, magnetic and magnetocaloric properties in ternary rare earth RE2T2X type intermetallic compounds.

Author

Zhang, Yikun

Subjects

*MAGNETIC properties, *MAGNETIC transitions, *MAGNETIC cooling, *MAGNETIC fields, *MAGNETOCALORIC effects, *INTERMETALLIC compounds, *RARE earth metals

Abstract

Abstract It is well known that rare earth (RE) based intermetallic compounds reveal various interesting magnetic properties depending on the crystallized structures and the constituent elements, paving the way for potential applications in different fields. Recent progresses regarding magnetic properties and magnetocaloric effect (MCE) in ternary rare earth RE 2 T 2 X (RE = Gd-Tm; T = Cu, Ni, Co; and X = Cd, In, Ga, Sn, Al) intermetallic compounds are reviewed in this paper. Some of them exhibit excellent MCE performances which make them attractive in the field of magnetic refrigeration at low temperature. With the aim of understanding the magnetocaloric characteristics of RE 2 T 2 X compounds, the crystal structure, magnetism and magnetic phase transition are also focused. The origin of the MCE together with the physics behind and the potential application of RE 2 T 2 X compounds are thoroughly considered. Highlights • Magnetic and magnetocaloric properties in RE 2 T2X compounds are reviewed. • The RE 2 T2X compounds show four types of crystallize structures. • Some of them exhibit excellent cryogenic magnetocaloric performances. • The origin of magnetocaloric effect in RE 2 T2X compounds is discussed. [ABSTRACT FROM AUTHOR]

Published

2019

6. Magnetocaloric Properties in TbNi B C Compound.

Author

Zhang, Yikun, Geng, Shuhua, and Wilde, Gerhard

Subjects

*MAGNETIC properties of nickel compounds, *MAGNETOCALORIC effects, *ANTIFERROMAGNETIC materials, *MAGNETIC fields, *MAGNETIC transitions

Abstract

The magnetic properties and magnetocaloric effect (MCE) in antiferromagnetic non-superconducting TbNiBC compound have been investigated in detail. Under low magnetic field changes and at low temperatures, the studied compound shows an inverse MCE which is due to the fact of antiferromagnetic ground state, whereas a normal reversible MCE under high magnetic field changes is observed which is related to the field-induced first-order metamagnetic transition from antiferromagnetic to ferromagnetic states. For the magnetic field change of 0-7 T the values of maximal magnetic entropy change ( $-\Delta S_{\mathrm {M}}^{\max } )$ , refrigerant capacity (RC) and relative cooling power (RCP) for the present TbNiBC are evaluated to be 11.1 J/kg/K, 225 J/kg and 296 J/kg, respectively. [ABSTRACT FROM AUTHOR]

Published

2016

7. Magnetism and Large Magnetocaloric Effect in GdNiBC Compound.

Author

Zhang, Yikun and Wilde, Gerhard

Subjects

*MAGNETOCALORIC effects, *NICKEL alloys, *MAGNETIC properties of metals, *HEAT capacity, *MAGNETIC transitions

Abstract

The magnetic and magnetocaloric properties in GdNiBC compound have been investigated by magnetization and heat capacity measurements. The compound exhibits a paramagnetic to ferromagnetic transition at TC\sim 15 K. A large reversible magnetocaloric effect has been observed and accompanied by a second-order magnetic phase transition at TC . The maximum magnetic entropy change ( -\Delta SM^{\mathrm {max}} ) and adiabatic temperature change ( \Delta T\mathrm {ad}^{\mathrm {max}} ) are 24.9 J/kg K and 13 K, for a magnetic field change of 0–7 T, respectively. The corresponding relative cooling power is 801 J/kg. [ABSTRACT FROM AUTHOR]

Published

2015

8. Structural and magnetic properties of Gd4Ga2O9 oxide with a large cryogenic magnetocaloric effect.

Author

Chen, Wang, Yin, Xunqing, Lin, Junli, Hao, Weixiang, and Zhang, Yikun

Subjects

*MAGNETIC entropy, *MAGNETOCALORIC effects, *MAGNETIC properties, *MAGNETICS, *MAGNETIC fields, *MAGNETIC cooling

Abstract

The magnetocaloric effect has been extensively investigated in various types of magnetic solids to not only develop practical magnetic cooling applications but also deepen the understanding of these materials' underlying inherent properties. Through experimental determination and theoretical calculation, we conducted a systematic investigation of Gd 4 Ga 2 O 9 oxide in terms of its structural, magnetic, and magnetocaloric properties and found it to crystallize in a monoclinic structure belonging to the space group P 2 1 / c and to possess an antiferromagnetic semiconducting ground state. The consistent elements were uniformly distributed up to the nanoscale and presented as Gd3+, Ga3+, and O 2 states, respectively. The magnetocaloric performances of Gd 4 Ga 2 O 9 oxide were checked according to the parameters of maximum magnetic entropy change, refrigerant capacity, and temperature-averaged entropy changes (lift of 5 K), which were determined to be 25.77 J/kgK, 218.27 J/kg, and 23.43 J/kgK under 0–7 T magnetic field change. These parameters of Gd 4 Ga 2 O 9 oxide are comparable to those of some recently reported materials with prominent performances, which means that it can be considered for cryogenic magnetic cooling applications. [ABSTRACT FROM AUTHOR]

Published

2024

9. Structural and cryogenic magnetic properties of the REOCl (RE = Ho, Dy, Tb, and Gd) compounds.

Author

Wang, Xin, Hao, Weixiang, He, Ningzhou, Wang, Xinhua, Zhang, Yikun, and Yan, Mi

Subjects

*MAGNETIC properties, *MANGANITE, *RARE earth metals, *MAGNETIC entropy, *MAGNETOCALORIC effects, *MAGNETIC cooling, *MAGNETIC fields

Abstract

We herein provided a systematical determination of the structural and magnetic properties, especially of the magnetocaloric effect (MCE) and magnetocaloric performances of four rare-earth oxychlorides, i. e., the RE OCl (RE = Ho, Dy, Tb and Gd) compounds. The studied RE OCl compounds are all crystallized in the tetragonal matlockite structure (P 4/ nmm space group) and the RE , O, and Cl elements are with the RE 3+, O2−, and Cl− valence states, respectively. The DyOCl, TbOCl and GdOCl compounds reveal an antiferromagnetic transition at around approximate 9.5, 3.7 and 4.8 K, respectively. The magnetocaloric performances are checked by the maximum magnetic entropy change, relative cooling power, and temperature-averaged entropy change with 5 K lift, which are found to be 14.16 J/kgK, 375.55 J/kg and 13.89 J/kgK for HoOCl, to be 14.88 J/kgK, 488.14 J/kg, and 14.60 J/kgK for DyOCl, to be 14.59 J/kgK, 419.67 J/kg, and 14.42 J/kgK for TbOCl, and to be 16.16 J/kgK, 213.68 J/kg, and 14.39 J/kgK for GdOCl, with the magnetic field change of 0–7 T, respectively. [ABSTRACT FROM AUTHOR]

Published

2024

10. Crystal structure, magnetic properties, and magnetocaloric effect in B-site disordered RE2CrMnO6 (RE = Ho and Er) perovskites.

Author

Wu, Bingbing, Guo, Dan, Wang, Yaming, and Zhang, Yikun

Subjects

*MAGNETOCALORIC effects, *MAGNETIC properties, *CRYSTAL structure, *MANGANESE alloys, *MAGNETIC entropy, *MAGNETIC fields, *MAGNETIC cooling

Abstract

In this work, polycrystalline oxides viz., Ho 2 CrMnO 6 (HCMO) and Er 2 CrMnO 6 (ECMO), were prepared using the sol-gel process, and their crystal structure, magnetic properties, and magnetocaloric effects (MCEs) were studied. X-ray refinement results demonstrate that both oxides exhibited the B -site disordered perovskite type structure (Pbnm space group). A ferromagnetic-paramagnetic phase transition as well as large reversible MCEs was also observed at Curie temperatures (T C) of ~6.1 and ~5.2 K for HCMO and ECMO, respectively. For a magnetic field change (ΔH) of 0–7 T, the maximum magnetic entropy change (-Δ S M), temperature-averaged entropy change (TEC 3), and relative cooling power (RCP) were estimated to be 11.03 J/kgK, 11.02 J/kgK, and 322.7 J/kg for HCMO, and 12.94 J/kgK, 12.80 J/kgK and 277.5 J/kg for ECMO. [ABSTRACT FROM AUTHOR]

Published

2020

11. Large conventional and inverse magnetocaloric effects in RE2Ga2Mg (RE = Tm, Er, Ho) compounds.

Author

Wang, Zhaoxing, Kai Reimann, Maximilian, Chen, Wang, Zhang, Yikun, and Pöttgen, Rainer

Subjects

*MAGNETOCALORIC effects, *MAGNETIC entropy, *MAGNETIC cooling, *MAGNETICS, *MAGNETIC fields, *MAGNETIC properties, *MANGANESE alloys, *LIQUID nitrogen

Abstract

• The RE 2 Ga 2 Mg (RE = Tm, Er, Ho) compounds were fabricated. • The magnetic and magnetocaloric properties were investigated. • Large conventional and inverse magnetocaloric effects were observed. • The Tm 2 Ga 2 Mg is considerable for cryogenic magnetic cooling. The Mo 2 FeB 2 -type compounds RE 2 Ga 2 Mg (RE = Tm, Er, Ho) (space group P 4/ mbm) exhibit a large magnetocaloric (MC) effect which makes them promising for use in cryogenic magnetic cooling applications. They exhibit low temperature metamagnetic nature below their Néel temperatures of 6.8, 11.7 and 18.4 K for Tm 2 Ga 2 Mg, Er 2 Ga 2 Mg and Ho 2 Ga 2 Mg, respectively. The magnetic entropy change, the temperature-averaged entropy change (3 K-lift), and the relative cooling power under a magnetic field change of 0–7 T are 15.6, 15.4 J/kgK and 275.8 J/kg for Tm 2 Ga 2 Mg; 13.2, 13.0 J/kgK and 268.0 J/kg for Er 2 Ga 2 Mg; as well as 9.1, 9.0 J/kgK and 223.0 J/kg for Ho 2 Ga 2 Mg, respectively. [ABSTRACT FROM AUTHOR]

Published

2024

12. Magnetic phase transitions and large magnetocaloric effects in equiatomic binary DyZn compound.

Author

Wang, Xiangjie, Wang, Lijuan, Ma, Qingmei, Sun, Gang, Zhang, Yikun, and Cui, Jianzhong

Subjects

*PHASE transitions, *MAGNETOCALORIC effects, *DYSPROSIUM, *CURIE temperature, *MAGNETIC fields

Abstract

The magnetic properties and magnetocaloric effect (MCE) in dysprosium zinc binary DyZn compound were studied. The compound reveals a paramagnetic-to-ferromagnetic transition together with a spin reorientation phenomenon at Curie temperatures of T C ∼135 and T SR ∼50 K, respectively. A large reversible MCE was observed in DyZn around T C . For the magnetic field change of 0–7 T, the values of maximum magnetic entropy change (–Δ S M max ), relative cooling power ( RCP ), and refrigerant capacity ( RC ) were 12.2 J/kg K, 895 J/kg, and 672 J/kg, respectively. [ABSTRACT FROM AUTHOR]

Published

2017

13. Magnetic properties, martensitic transformations and magnetocaloric performances in Ni44Mn45-xFexSn11 (x = 0–3) Heusler alloys.

Author

Ouyang, Jianlong, Tian, Yun, Xiao, Haibo, and Zhang, Yikun

Subjects

*MAGNETOCALORIC effects, *HEUSLER alloys, *MARTENSITIC transformations, *MAGNETIC properties, *MAGNETIC entropy, *TIN, *MAGNETIC fields

Abstract

The structural, magnetic, and magnetocaloric properties of Ni 44 Mn 45-x Sn 11 Fe x (x = 0, 1, 2 and 3) Heusler alloys have been studied detailly by means of X-ray diffraction, differential scanning calorimetry, and magnetization measurements. The martensitic transition temperature (T M) and austenite Curie temperature (T A C) increase gradually with increasing Fe content. Large differences in magnetization between the ferromagnetic austenite and weakly magnetic martensite phases and obvious thermal hysteresis have also been observed during the martensite transformation. With the magnetic field change up to 0–7 T, the maximum value of magnetic entropy changes reaches 26.7 and 23 J kg−1K−1 for x = 1 and 2, respectively, which are much larger than the undoped sample (9.8 J kg−1K−1). Whereas, the effective refrigerant capacity RC eff reduced due to Fe doping increased the hysteresis loss. The alloy for x = 1 has highest RC value of 172 (255) J kg−1 for a magnetic field change of 0–5 T (0–7 T), furthermore, a large magnetic entropy change and moderate RC eff has been obtained around room temperature. • Fe-doped Ni44Mn45-xSn11Fex (x = 0, 1, 2 and 3) Heusler alloys were fabricated. • Structural and magnetic properties of Ni44Mn45-xSn11Fex were investigated. • Considerable magnetocaloric performances in Ni44Mn44Sn11Fe were realized. [ABSTRACT FROM AUTHOR]

Published

2021

14. Observation of large magnetocaloric effect in ternary Er-based Er4CoCd compound.

Author

Guo, Dan, Wang, Yaming, Li, Huadong, Guan, Renguo, Xu, Hui, and Zhang, Yikun

Subjects

*MAGNETOCALORIC effects, *MAGNETIC entropy, *RIETVELD refinement, *MAGNETIC fields, *CURIE temperature, *MANGANESE alloys, *SPACE frame structures

Abstract

• The magnetism and magnetocaloric effect (MCE) were investigated in Er 4 CoCd compound. • A large magnetocaloric effect in Er 4 CoCd compound was observed. • The origin of MCE and its potential application in Er 4 CoCd were discussed. The Er-based compound Er 4 CoCd was synthesized successfully and its structural, magnetic together with magnetocaloric properties were investigated in detail. The Er 4 CoCd crystallized in a Gd 4 RhIn-type structure with the space group of F 4 ¯ 3 m , which was confirmed by Rietveld refinement. A ferromagnetic transition was observed around its Curie temperature (T C) of 12.5 K accompanied by a large magnetocaloric effect (MCE). The performance of MCE for Er 4 CoCd was evaluated by the isothermal maximal magnetic entropy (- Δ S M max) , the temperature averaged entropy change (TEC) at 10 K temperature lift [ TEC (10 K)], and the relative cooling power (RCP). The values of - Δ S M max , TEC (10 K), and RCP of Er 4 CoCd are 20.4 J/kg K, 19.2 J/kg K, and 503 J/kg under the magnetic field change (Δ H) of 0–5 T, respectively. [ABSTRACT FROM AUTHOR]

Published

2019