采用铜模铸造法制备了 Mn1.15 Fe0.85 P0.55 Si0.45化合物,并对其物相结构、显微组织及磁热效应进行了研究.结果表明,化合物具有六角 Mn5.64 P3型主相和少量 Mn3 Fe2 Si3杂相;化合物的居里温度为305 K,热滞为13.5 K;在0~2 T 外磁场下的最大等温磁熵变为12.2 J/(kg·K),远远高于纯 Gd.同时为了探索大磁熵变的来源,采用 Landau 相变理论和“普适曲线”方法研究了该化合物的磁相变特性,Arrott 曲线分析表明,该化合物在居里温度附近发生了明显的一级相变,而“普适曲线”理论分析表明,该化合物的磁相变介于一级和二级之间.
Mn1 .1 5 Fe0.85 P0.5 5 Si0.45 ingots were prepared by arc melting and copper mould casting technique.The mi-crostructure and magnetocaloric effects were investigated by X-ray diffraction,scanning electron microscope and physical property measurement system.The results show that Mn1 .1 5 Fe0.85 P0.5 5 Si0.45 compound crystallizes into the hexagonal Mn5 .64 P3-type structure with small amount of Mn3 Fe2 Si3 impurity phases.The Curie temperature and thermal hysteresis are about 305 and 13.5 K respectively.The maximal magnetic entropy change of 12.2 J/(kg·K)in a field change of 2 T was obtained,which was much larger than that of pure Gd.To analyze the na-ture of the magnetic phase transition in detail,we have carried out the study of the critical behavior near the Cu-rie temperature for the compound by Landau theory and universal curves theory.The Arrott plots prove that the compound undergo a first-order magnetic transition,however universal curves theory indicate that the magnetic transition was between first-order and second-order.
参考文献
| [1] | Zeng Dechang;Zheng Zhigang;Zhong Xichun et al.De-velopments and applications of magnetic refrigeration technique[J].Electrical Appliances,2008,1:50-55. |
| [2] | K. A. Gschneidner Jr;V. K. Pecharsky .Recent developments in magnetic refrigeration[J].Materials Science Forum,1999(0):69-76. |
| [3] | Zhang, J.L.;Zheng, Z.G.;Cao, W.H.;Shek, C.H. .Magnetic behavior of Gd_4Co_3 metallic glass[J].Journal of Magnetism and Magnetic Materials,2013(1):157-161. |
| [4] | Z.G. Zheng;X.C. Zhong;Z.W. Liu;D.C. Zeng;V. Franco;J.L. Zhang.Magnetocaloric effect and critical behavior of amorphous (Gd_4Co_3)_(1-x)Si_x alloys[J].Journal of Magnetism and Magnetic Materials,2013:184-188. |
| [5] | S. Fujieda;A. Fujita;K. Fukamichi .Large magnetocaloric effect in La(Fe_(x)Si_(1-x))_(13) itinerant-electron metamagnetic compounds[J].Applied physics letters,2002(7):1276-1278. |
| [6] | Feng-xia Hu;Bao-gen Shen;Ji-rong Sun;Zhao-hua Cheng;Guang-hui Rao;Xi-xiang Zhang .Influence of negative lattice expansion and metamagnetic transition on magnetic entropy change in the compound LaFe_(11.4)Si_(1.6)[J].Applied physics letters,2001(23):3675-3677. |
| [7] | 张铁邦,付浩,陈云贵,唐永柏,涂铭旌.快淬低纯Gd5Si2Ge2合金的结构和磁熵变[J].功能材料,2005(04):513-515. |
| [8] | H. Fu;X.T. Zu;X. He .The effect of low temperature annealing on the structure of Gd_5Si_2Ge_2 alloy[J].Journal of Alloys and Compounds: An Interdisciplinary Journal of Materials Science and Solid-state Chemistry and Physics,2007(1/2):89-92. |
| [9] | Pecharsky VK.;Gschneidner KA. .Gd-5(SixGe1-x)(4): An extremum material[J].Advanced Materials,2001(9):683-686. |
| [10] | von Ranke PJ.;de Oliveira NA.;Gama S. .Theoretical investigations on giant magnetocaloric effect in MnAs1-xSbx[J].Physics Letters, A,2004(4):302-306. |
| [11] | H. Wada;Y. Tanabe .Giant magnetocaloric effect of MnAs_(1-x)Sb_(x)[J].Applied physics letters,2001(20):3302-3304. |
| [12] | Tegus O;Brück E;Buschow K H J et al.Transition-metal-based magnetic refrigerants for room-temperature applications[J].Nature(London),2002,41 5:150-152. |
| [13] | O. Tegus;E. Bruck;X.W. Li .Tuning of the magneto-caloric effects in MnFe(P,As) by substitution of elements[J].Journal of Magnetism and Magnetic Materials,2004(3):2389-2390. |
| [14] | 张虎,刘丹敏,王少博,肖卫强,张振路,岳明,张久兴.Mn2-xFexP1-yGey(x=0.8、0.9,y=0.2、0.24、0.26)磁制冷材料的制备工艺及磁热性能研究[J].功能材料,2013(21):3103-3107. |
| [15] | Wang, G.F.;Zhao, Z.R.;Zhang, X.F.;Song, L.;Tegus, O. .Analysis of the first-order phase transition of (Mn,Fe)2 (P,Si,Ge) using entropy change scaling[J].Journal of Physics, D. Applied Physics: A Europhysics Journal,2013(29):295001-1-295001-6. |
| [16] | E. Bruck;N.T. Trung;Z.Q. Ou .Enhanced magnetocaloric effects and tunable thermal hysteresis in transition metal pnictides[J].Scripta materialia,2012(6):590-593. |
| [17] | Dung N H;Zhang L;Ou Z Q et al.From first-order magneto-elastic to magneto-structural transition in(Mn, Fe)1.9 5 P0.50 Si0.50 compounds[J].Applied Physics Letters,2011,99(92511):1-3. |
| [18] | Thanh DTC;Brueck E;Trung NT;Klaasse JCP;Buschow KHJ;Ou ZQ;Tegus O;Caron L .Structure, magnetism, and magnetocaloric properties of MnFeP1-xSix compounds[J].Journal of Applied Physics,2008(7 Pt.2):B7318-1-B7318-3-0. |
| [19] | 钟喜春,曾德长,刘正义,魏兴钊.室温磁致冷工质的选用原则及制备技术[J].材料科学与工程,2002(03):441-444,421. |
| [20] | L. Song;G.F. Wang;Z.Q. Ou .Magnetic properties and magnetocaloric effect of MnFeP_(0.5)Ge_(0.5-x)Si_x compounds[J].Journal of Alloys and Compounds: An Interdisciplinary Journal of Materials Science and Solid-state Chemistry and Physics,2009(1/2):388-390. |
| [21] | 邓晓军,刘丹敏,岳明,黄清镇,赵金良,张久兴.SPS制备Mn1.1Fe0.9P0.8Ge0.2Bx化合物磁热性能的研究[J].稀有金属材料与工程,2013(07):1450-1453. |
| [22] | Ou, Z.Q.;Zhang, L.;Dung, N.H.;Van Eijck, L.;Mulders, A.M.;Avdeev, M.;Van Dijk, N.H.;Brück, E..Neutron diffraction study on the magnetic structure of Fe 2_P-based Mn_(0.66)Fe_(1.29)P_(1-x)Si_x melt-spun ribbons[J].Journal of Magnetism and Magnetic Materials,2013:80-85. |
| [23] | Dung, N.H.;Zhang, L.;Ou, Z.Q.;Zhao, L.;Van Eijck, L.;Mulders, A.M.;Avdeev, M.;Suard, E.;Van Dijk, N.H.;Brück, E. .High/low-moment phase transition in hexagonal Mn-Fe-P-Si compounds[J].Physical review, B. Condensed matter and materials physics,2012(4):045134-1-045134-7. |
| [24] | Nguyen Huu Dung;Lian Zhang;Zhi Qiang Ou .Magnetoelastic coupling and magnetocaloric effect in hexagonal Mn-Fe-P-Si compounds[J].Scripta materialia,2012(12):975-978. |
| [25] | Feng Z;Wu W;Zhao H et al.The influence of Dy ad-ditions on the magnetocaloric effect in Gd0.9 7 V0.03 alloys[J].Materials Characterization,2008,60(4):312-315. |
| [26] | Bonilla C M;Herrero-Albillos J;BartoloméF et al.Uni-versal behavior for magnetic entropy change in magneto-caloric materials:An analysis on the nature of phase transitions[J].Physical Review B,2010,81:224424-224431. |
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