Your search keyword '"Zhang, Yikun"' showing total 10 results

1. Giant refrigerant capacity in equi-atomic HoErGdCuNi amorphous ribbons.

Author

Zhang, Yikun, Guo, Dan, Xu, Hui, Ren, Zhongming, and Wilde, Gerhard

Subjects

*MAGNETOCALORIC effects, *MAGNETIC cooling, *MAGNETIC entropy, *LIQUID nitrogen, *MAGNETIC materials

Abstract

The microstructure, cryogenic magnetic properties, magneto-caloric effect (MCE) and refrigeration performance of equi-atomic HoErGdCuNi ribbons have been investigated. Fully amorphousized structure with uniform distribution for all constituent elements is obtained. A table-like MCE that covers the temperature region from liquid nitrogen to liquid hydrogen is observed, which leads to a giant refrigerant capacity. Accordingly, the maximum magnetic entropy change (- Δ S M max) , temperature-averaged entropy change [ TEC (10)] and refrigerant capacity (RC) are 15.8 J/kgK, 15.7 J/kgK and 903 J/kg, respectively, at the magnetic field change (Δ H) of 0–7 T. The equi-atomic HoErGdCuNi amorphous ribbons with good MCE parameters especially those with large RC values, are an attractive candidate for cryogenic magnetic refrigeration materials. • Magnetism and magnetocaloric effect (MCE) of HoErGdCuNi ribbons were investigated. • A giant refrigerant capacity (RC) in HoErGdCuNi ribbons was obtained. • The origin of MCE and its potential application in HoErGdCuNi were discussed. [ABSTRACT FROM AUTHOR]

Published

2019

2. Low field induced large magnetic entropy change in the amorphousized Tm60Co20Ni20 ribbon.

Author

Zhang, Yikun, Guo, Dan, Li, Huadong, Geng, Shuhua, Wang, Jiang, Li, Xi, Xu, Hui, Ren, Zhongming, and Wilde, Gerhard

Subjects

*AMORPHOUS substances, *COBALT compounds, *MAGNETIC entropy, *MAGNETIC transitions, *LOW temperature engineering

Abstract

The magnetic properties and magnetic entropy change of amorphousized Tm 60 Co 20 Ni 20 ribbon were systematically studied. The results indicate that the Tm 60 Co 20 Ni 20 amorphous ribbon reveals a second order magnetic transition (paramagnetic to ferromagnetic state) based on the Arrott plots and rescaled magnetic entropy change curves. A large magnetic entropy change is achieved around its Curie temperature of T C ∼6.7 K. Under the magnetic field change (Δ Η ) of 0–5 T, the maximum values of magnetic entropy change (−Δ S M max ) and relative cooling power ( RCP ) are 17.1 J/kg K and 273 J/kg, respectively. In particular, under a relative low Δ Η of 0–2 T, a large magnetic entropy change of 11.8 J/kg K reaches, making it attractive in the field of low-temperature magnetic refrigeration. [ABSTRACT FROM AUTHOR]

Published

2018

3. Magnetic properties and magnetocaloric effect in TmZnAl and TmAgAl compounds.

Author

Zhang, Yikun, Hou, Long, Ren, Zhongming, Li, Xi, and Wilde, Gerhard

Subjects

*MAGNETOCALORIC effects, *MAGNETIC properties, *INTERMETALLIC compounds, *CURIE temperature, *MAGNETIC entropy

Abstract

The magnetic and magnetocaloric properties in the equiatomic intermetallic compounds of TmZnAl and TmAgAl have been investigated. The compounds undergo a second order magnetic transition from paramagnetic to ferromagnetic state around its own Curie temperatures T C ∼2.8 K and 3.3 K for TmZnAl and TmAgAl, respectively. A considerable reversible magnetocaloric effect (MCE) was observed at low temperature. For a magnetic field change of 7 T, the maximum values of magnetic entropy change (−Δ S M max ) and relative cooling power ( RCP ) are 11.8 J/kg K and 289 J/kg for TmZnAl, respectively, and the corresponding values for TmAgAl are 14.1 J/kg K and 315 J/kg. [ABSTRACT FROM AUTHOR]

Published

2016

4. Magnetic properties and magnetocaloric effect in ternary REAgAl (RE = Er and Ho) intermetallic compounds.

Author

Zhang, Yikun, Yang, Baijun, and Wilde, Gerhard

Subjects

*MAGNETOCALORIC effects, *CURIE temperature, *MAGNETIC entropy, *FERROMAGNETISM, *PHASE transitions, MAGNETIC properties of intermetallic compounds

Abstract

Magnetism and magnetocaloric effect in RE AgAl ( RE = Er and Ho) intermetallic compounds have been studied. Both compounds undergo a second order magnetic phase transition from paramagnetic to ferromagnetic state. A large reversible magnetocaloric effect was observed around its own Curie temperatures T C ∼ 14 and 18 K for ErAgAl and HoAgAl, respectively. For a field change of 0–7 T, the maximum magnetic entropy change reaches 13.7 and 13.8 J/kg K for RE = Er and Ho, respectively. The corresponding relative cooling powers are evaluated to be 398 and 525 J/kg. [ABSTRACT FROM AUTHOR]

Published

2015

5. Glass forming ability, magnetic properties and cryogenic magnetocaloric effects in RE60Co20Al20 (RE = Ho, Er, Tm) amorphous ribbons.

Author

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

Subjects

*MAGNETOCALORIC effects, *MAGNETIC properties, *MAGNETIC transitions, *MAGNETIC cooling, *MAGNETIC entropy, *MANGANESE alloys, *AMORPHOUS alloys

Abstract

The rare-earths (RE) based amorphous materials with large magnetocaloric (MC) effects and excellent glass forming ability (GFA) have been recognized as promising candidates for magnetic refrigeration (MR). In this work, the RE 60 Co 20 Al 20 (RE = Ho, Er, Tm) amorphous ribbons were successfully fabricated and systematically determined with respect to the GFA, magnetic properties and MC effects. A second order magnetic phase transition (MPT) from ferromagnetic to paramagnetic (FM to PM) without noticeable field or thermal hysteresis has been observed around the Curie temperatures, T C ~ 22.3 K for Ho 60 Co 20 Al 20 , ~ 10.3 K for Er 60 Co 20 Al 20 , and ~ 5.0 K for Tm 60 Co 20 Al 20 , respectively. The MC parameters including the maximum magnetic entropy change (| Δ S M max |), temperature-averaged entropy change with 3 K lift [ TEC (3 K)], and relative cooling powder/refrigerant capacity (RCP/RC) have been determined to check the MC performances, and the corresponding values are determined to be 14.16, 15.57 and 15.06 J/kgK, to be14.04, 15.38 and 14.78 J/kgK, and to be 625.0/478.7, 505.7/391.8 and 334.0/243.4 J/kg for Ho 60 Co 20 Al 20 , Er 60 Co 20 Al 20 and Tm 60 Co 20 Al 20 under the field change Δμ 0 H = 5 T, respectively. The present results indicate that RE 60 Co 20 Al 20 (RE = Ho, Er, Tm) amorphous ribbons are considerable for cryogenic MR application. • The RE 60 Co 20 Al 20 (RE = Ho, Er, Tm) amorphous ribbons are fabricated. • The glass forming ability in RE 60 Co 20 Al 20 amorphous ribbons was investigated. • Large magnetocaloric effect in RE 60 Co 20 Al 20 has been observed. • RE 60 Co 20 Al 20 ribbons are considerable for cryogenic magnetic refrigeration. [ABSTRACT FROM AUTHOR]

Published

2022

6. Structural, magnetic properties and magneto-caloric performances in the antiferromagnetic RECoSi2 (RE = Er and Tm) compounds.

Author

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

Subjects

*MAGNETIC properties, *MAGNETOCALORIC effects, *MAGNETIC cooling, *MAGNETIC entropy, *RARE earth metals, *RIETVELD refinement, *ERBIUM, *MANGANESE alloys

Abstract

The ternary rare earth RE CoSi 2 (RE = Er and Tm) intermetallic compounds were synthesized by means of arc-melting technique and their crystal structure, magnetism and magneto-caloric effect (MCE) were studied systematically. Both ErCoSi 2 and TmCoSi 2 crystallize in a CeNiSi 2 -type structure (Cmcm space group) confirmed by FULLPROF Rietveld refinement. Magnetization data indicates the antiferromagnetic (AFM) ground state for both RE CoSi 2 compounds, and a magnetic field-induced ferromagnetic (FM) transition occurs below the Neel temperature T N ∼6.9 K for ErCoSi 2 and ∼5.4 K for TmCoSi 2. Considerable reversible MCE in ErCoSi 2 and TmCoSi 2 was observed. The MCE performances of RE CoSi 2 are evaluated by -Δ S M max (maximal magnetic entropy change), TEC (3) (temperature averaged entropy change), and RCP (relative cooling power) with the values of 7.1 J/kg K, 6.8 J/kg K and 165.9 J/kg for ErCoSi 2 , as well as 8.7 J/kg K, 8.5 J/kg K and 152.9 J/kg for TmCoSi 2 , respectively, under Δ H (field change) of 0–50 kOe. Image 1 • CeNiSi 2 -type RE CoSi 2 (RE = Er and Tm) compounds were fabricated. • AFM ordering at T N ∼6.9 K for ErCoSi 2 and ∼5.4 K for TmCoSi 2. • A field-induced AFM to FM transition for both compounds occur below T N. • Considerable values of -Δ S M max, TEC , RC and RCP were found. • RE CoSi 2 compounds are also considerable for cryogenic magnetic cooling. [ABSTRACT FROM AUTHOR]

Published

2020

7. Structural, magnetic and magnetocaloric properties in RE2Ni1.5Ga2.5 (RE = Dy, Ho, Er and Tm) compounds.

Author

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

Subjects

*MAGNETIC properties, *MAGNETIC transitions, *MANGANESE alloys, *MAGNETIC cooling, *ERBIUM, *MAGNETIC entropy, *MAGNETIC structure

Abstract

The crystal structure together with the magnetic and magnetocaloric properties in RE 2 Ni 1.5 Ga 2.5 (RE = Dy, Ho, Er and Tm) have been investigated systematically. All the RE 2 Ni 1.5 Ga 2.5 compounds crystallize in a CaIn 2 -type structure of (P63/mmc space group). A second-ordered magnetic phase transition (SOPT) from ferromagnetic to paramagnetic (FM to PM) is occurred in RE 2 Ni 1.5 Ga 2.5 compounds with the Curie temperatures (T C) of approximately 16.1, 10.6, 4.1 and below 2 K for RE of Dy, Ho, Er and Tm, respectively. The magnetocaloric parameters including magnetic isothermal entropy change/temperature-averaged magnetic entropy change -Δ S M max/ TEC (5) and relative cooling power RCP are calculated with the values of 10.01/9.92 J/kg K and 418.6 J/kg for Dy 2 Ni 1.5 Ga 2.5 , 20.12/19.65 J/kg K and 644.1 J/kg for Ho 2 Ni 1.5 Ga 2.5 , 18.07/17.69 J/kg K and 447.1 J/kg for Er 2 Ni 1.5 Ga 2.5 , as well as 18.22/16.75 J/kg K and 330.7 J/kg for Tm 2 Ni 1.5 Ga 2.5 with magnetic field change (Δ H) of 0–7 T, respectively. Notably, Ho 2 Ni 1.5 Ga 2.5 exhibits ralatively high magnetocaloric parameters, which suggests that Ho 2 Ni 1.5 Ga 2.5 is a competitive candidate among the MCE materials in the field of cryogenic magnetic refrigeration (MR). • Magnetic properties and MCE in RE 2 Ni 1.5 Ga 2.5 compounds were studied. • Large values of -ΔS M max, TEC and RCP were observed at low temperature. • Ho 2 Ni 1.5 Ga 2.5 compound is competitive for cryogenic magnetic cooling. [ABSTRACT FROM AUTHOR]

Published

2020

8. Magnetic properties and magneto-caloric performances in RECo2B2C (RE = Gd, Tb and Dy) compounds.

Author

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

Subjects

*MAGNETIC properties, *MANGANITE, *MAGNETIC cooling, *MAGNETIC entropy, *RARE earth metals, *MANGANESE alloys, *MAGNETIC fields, *CURIE temperature

Abstract

We present a detailed investigation of the crystal structure, magnetism and magneto-caloric performances of RE Co 2 B 2 C (RE = Gd, Tb and Dy) compounds. All compounds are described with a LuNi 2 B 2 C-type crystallographic structure (I 4/ mmm space group). A second-ordered paramagnetic to ferromagnetic (PM-FM) transition is observed in RE Co 2 B 2 C compounds around their Curie temperatures (T C) of 17.2, 5.3 and 7.7 K, and induced a considerable magneto-caloric effect (MCE) for GdCo 2 B 2 C, TbCo 2 B 2 C and DyCo 2 B 2 C, respectively. The magneto-caloric performances for RE Co 2 B 2 C were characterized by the isothermal magnetic entropy (- Δ S M max) , temperature averaged entropy change (TEC) with three different temperature lifts (3, 5 and 10 K), and relative cooling power (RCP). The corresponding values of - Δ S M max , TEC (3 K) and RCP under the magnetic field change (Δ H) of 0–5 T, are 10.34 J/kg-K, 10.23 J/kg-K, and 238.1 J/kg for GdCo 2 B 2 C, 18.09 J/kg-K, 17.83 J/kg-K, and 438.2 J/kg for TbCo 2 B 2 C, as well as 17.79 J/kg-K, 17.72 J/kg-K, and 480.1 J/kg for DyCo 2 B 2 C, respectively. • Magnetic properties and MCE in RE Co 2 B 2 C compounds were studied. • Large values of -ΔS M max, TEC, RC and RCP were observed at low temperature. • RE Co 2 B 2 C compounds are competitive for cryogenic magnetic cooling. [ABSTRACT FROM AUTHOR]

Published

2020

9. Magnetic phase transitions and large magnetic entropy change with a wide temperature span in HoZn.

Author

Li, Lingwei, Yuan, Ye, Zhang, Yikun, Pöttgen, Rainer, and Zhou, Shengqiang

Subjects

*MAGNETIC transitions, *MAGNETIC entropy, *EFFECT of temperature on metals, *PHASE transitions, *MAGNETIC properties of metals

Abstract

CsCl-type HoZn undergoes two successive magnetic phase transitions: (i) paramagnetic to ferromagnetic (FM) at T C ∼ 72 K and (ii) a spin reorientation (SR) at T SR ∼ 26 K. Magnetization and modified Arrott plots indicate that HoZn undergoes a second-order magnetic phase transition around T C . The obtained critical exponents have some small deviations from the mean-field theory, indicating a short range or a local magnetic interaction which is properly related to the coexistence of FM and SR transitions at low temperature. Two successive magnetic transitions in HoZn induce one broad pronounced peak together with a shoulder in the temperature dependence of the magnetic entropy change −Δ S M ( T ) curves, resulting in a wide temperature range with a large relative cooling power ( RCP ). For a field change of 0–7 T, the maximum value of −Δ S M is 15.2 J/kg K around T C with a large RCP value of 1124 J/kg. The large reversible magnetocaloric effect (MCE) and RC indicate that HoZn is a good candidate for active magnetic refrigeration. [ABSTRACT FROM AUTHOR]

Published

2015

10. Direct and inverse magnetocaloric effects in the antiferromagnetic rare earth (RE) rich RE6Ni2.25Al0.75 (RE = Dy, Ho and Er) compounds.

Author

Gu, Yuming, Wang, Xin, Li, Shuo, Ying, Jiayu, and Zhang, Yikun

Subjects

*MAGNETOCALORIC effects, *RARE earth metals, *MAGNETIC cooling, *MAGNETIC transitions, *MAGNETIC entropy, *RARE earth metal alloys, *MANGANESE alloys

Abstract

The magnetic refrigeration (MR) by utilizing the magnetocaloric effect (MCE) of magnetic solids has been considered a promising, environmentally benign, energy-efficient cooling technology. However, the lack of promising magnetic substances has slowed the development of its active application. To identify suitable candidate materials, we herein identified the structural and magnetic properties together with the MCE and magnetocaloric performances of rare earth (RE) rich RE 6 Ni 2.25 Al 0.75 (RE = Dy, Ho and Er) compounds. All the RE 6 Ni 2.25 Al 0.75 compounds are confirmed to crystallized in orthogonal Ho 6 Co 2 Ga-type structure and underwent paramagnetic to antiferromagnetic magnetic transitions. Moreover, large direct (conventional) and inverse MCEs have been observed in all the RE 6 Ni 2.25 Al 0.75 compounds. The values of peak magnetic entropy changes, temperature-averaged magnetic entropy changes with 5 K-lift and relative cooling powers under magnetic field change of 0–7 T are evaluated to be − 4.44 J/kg-K, − 4.38 J/kg-K and 230.6 J/kg for Dy 6 Ni 2.25 Al 0.75 , to be − 12.68 J/kg-K, − 12.26 J/kg-K and 378.2 J/kg for Ho 6 Ni 2.25 Al 0.75 , and to be − 17.52 J/kg-K, − 17.33 J/kg-K and 465.7 J/kg for Er 6 Ni 2.25 Al 0.75 , respectively. • The RE6Ni2.25Al0.75 (RE = Dy, Ho and Er) compounds are fabricated. • The structural and magnetic properties were investigated. • Large direct and inverse magnetocaloric effects were observed. • The Er6Ni2.25Al0.75 is considerable for cryogenic magnetic refrigeration. [ABSTRACT FROM AUTHOR]

Published

2023