[1]马思遥,张学习,钱明芳,等.Ni-Mn基铁磁记忆合金韧化[J].中国材料进展,2024,43(05):050-59.
MA SiyaoZHANG XuexiQIAN MingfangJIA Zhenggang,ZHONG Shijiang,GENG Lin.Toughening of polycrystalline Ni-Mn-based ferromagnetic shape memory alloys[J].MATERIALS CHINA,2024,43(05):050-59.
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Ni-Mn基铁磁记忆合金韧化()
中国材料进展[ISSN:1674-3962/CN:61-1473/TG]
- 卷:
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43
- 期数:
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2024年第05期
- 页码:
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050-59
- 栏目:
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- 出版日期:
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2024-05-30
文章信息/Info
- Title:
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Toughening of polycrystalline Ni-Mn-based ferromagnetic shape memory alloys
- 作者:
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马思遥; 张学习; 钱明芳; 耿林
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哈尔滨工业大学 材料科学与工程学院,哈尔滨150001
- Author(s):
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MA SiyaoZHANG Xuexi1QIAN Mingfang2JIA Zhenggang; ZHONG Shijiang; GENG Lin
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(School of materials science and engineeringHarbin Institute of TechnologyHarbin 150001China)
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- 关键词:
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铁磁形状记忆合金; Ni-Mn-Ga合金; 韧化; 固体制冷; 弹热效应; 全d轨道杂化
- Keywords:
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Ferromagnetic shape memory alloy; Ni-Mn-Ga alloy; Toughening; Solid-state refrigeration; Elastocaloric effect; All d-orbital hybridization; 0; 0; 0; 0; 0; C; 1
- 摘要:
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固态制冷技术由于其具有环保、高效、节能的特点,因而有望取代传统的气体压缩式制冷技术。Ni-Mn基铁磁形状记忆合金由于具有磁热效应、弹热效应、压热效应、磁阻、磁致应变等多功能特性而受到了人们的广泛关注。近年来,材料工程师及科学家们对Ni-Mn基磁形状记忆合金的热效应开展了一列深入的研究并取得了众多研究成果。Ni-Mn基合金的应用。本文综述了传统的过渡族元素、稀土元素和类金属元素掺杂引起的固溶强化、第二相强化、细晶强化和晶界净化与修饰对Ni-Mn基合金韧性的影响规律,比较了不同方法在Ni-Mn合金韧性增强方面的优缺点,Ni-Mn基合金的研究和发展方向,对于促进Ni-Mn基合金在功能器件等领域的应用具有重要的意义。
- Abstract:
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The solid-state refrigeration technology is expected to replace the traditional gas compression refrigeration technology because of its environmental protection, high efficiency, and energy saving characteristics. Among various competitive solid-state cooling materials, Ni-Mn-based ferromagnetic memory alloys have received widespread attention due to their multifunctional properties such as magnetocaloric effect, elastocaloric effect, barocaloric effect, magnetoresistance, and magnetic field induced strain, etc. In recent years, materials engineers and scientists have carried out a series of in-depth studies on the thermal effects of Ni-Mn-based magnetic shape memory alloys and have obtained numerous research results. However, the poor toughness and cyclic stability greatly limited their practical application in solid-state refrigeration region. This article summarizes the influence of element doping, microstructure design and size effect on the strength and toughness of Ni-Mn based ferromagnetic shape memory alloys, where the mechanisms are also summarized. The pros and cons of different methods in Ni-Mn alloy toughness enhancement are compared. The main problems existing in orbital hybridization methods are analyzed. The main research direction of Ni-Mn based ferromagnetic memory alloy is prospected, which has important theoretical significance and research value for promoting the application of Ni-Mn based ferromagnetic memory alloy in various fields
参考文献/References:
[1] LI D,LI Z,YANG J,et al. Scripta Mater[J],2019,163:116-120.
[2] TANG X,FENG Y,WANG H,et al. Appl Phys Lett[J],2019,114(3):033901.
[3] QU Y H,CONG D Y,LI S H,et al. Acta Mater[J],2018,151:41-55.
[4] REIS M S. Coordin Chem Rev[J],2020,417:213357.
[5] MOYA X,KAR-NARAYAN S,MATHUR N D. Nat Mater[J],2014,13(5):439-450.
[6] NEESE B,CHU B,LU S G,et al. Science[J],2008,321(5890):821-823.
[7] LIU J,GOTTSCHALL T,SKOKOV K P,et al. Nat Mater[J],2012,11(7):620-626.
[8] GUILLOU F,PORCARI G,YIBOLE H,et al. Adv Mater[J],2014,26(17):2671-2675.
[9] BONNOT E,ROMERO R,MA?OSA L,et al. Phys Rev Lett[J],2008,100(12)
[10] VELIAN A,CUMMINS C C. Science[J],2015,348(6238):1001-1004.
[11] ULLAKKO K,HUANG J K,KANTNER C,et al. Appl Phys Lett[J],1996,69(13):1966-1968.
[12] GRAF T,FELSER C,PARKIN S S P. Prog Solid State Ch[J],2011,39(1):1-50.
[13] KHOVAYLO V V,BUCHELNIKOV V D,KAINUMA R,et al. Phys Rev B[J],2006,73(14)
[14] AKSOY S,KRENKE T,ACET M,et al. Appl Phys Lett[J],2007,91(25):251915.
[15] PLANES A,MA?OSA L,ACET M. Journal of Physics: Condensed Matter[J],2009,21(23):233201.
[16] YAN H,WANG L,LIU H,et al. Mater Design[J],2019,184:108180.
[17] HUANG X,WANG L,LIU H,et al. Intermetallics[J],2019,113:106579.
[18] YAN H,ZHAO Y,LIU H,et al. J Alloy Compd[J],2020,821:153481.
[19] CZAJA P,CHULIST R,TOKARSKI T,et al. J Mater Sci[J],2018,53(14):10383-10395.
[20] CHERNENKO V A,VILLA E,SALAZAR D,et al. Appl Phys Lett[J],2016,108(7):071903.
[21] WANG J,YU Q,XU K,et al. Scripta Mater[J],2017,130:148-151.
[22] WILKES K,LIAW P.JOM[J],2000,52(10):45-51
[23] LU B,ZHANG P,XU Y,et al. Mater Lett[J],2015,148:110-113.
[24] ROY S,BLACKBURN E,VALVIDARES S M,et al. Physical Review. B, Condensed matter and materials physics[J],2009,79(23): 235127
[25] GAUTAM B R,DUBENKO I,MABON J C,et al. J Alloy Compd[J],2009,472(1-2):35-39.
[26] WANG J,JIANG C. Scripta Mater[J],2010,62(5):298-300.
[27] WANG J,WANG H,JIANG C. Mater Sci Eng: A[J],2013,578:256-259.
[28] LI Y,SUN W,ZHAO D,et al. Scripta Mater[J],2017,130:278-282.
[29] XUE F,DAI-NING F,KEH-CHIH H. Chinese Phys Lett[J],2002,19:1547.
[30] CHERECHUKIN A A,DIKSHTEIN I E,ERMAKOV D I,et al. Physics letters. A[J],2001,291(2-3):175-183.
[31] WANG H B,CHEN F,GAO Z Y,et al. Mater Sci Eng: A[J],2006,438-440:990-993.
[32] FENG Y,SUI J H,GAO Z Y,et al. Mater Sci Eng: A[J],2009,507(1-2):174-178.
[33] HUANG L,CONG D Y,SUO H L,et al. Appl Phys Lett[J],2014,104(13):132407.
[34] KRENKE T,DUMAN E,ACET M,et al. Nat Mater[J],2005,4(6):450-454.
[35] YU S Y,MA L,LIU G D,et al. Appl Phys Lett[J],2007,90(24):242501.
[36] ZHANG B,ZHANG X X,YU S Y,et al. Appl Phys Lett[J],2007,91(1):012510.
[37] KAINUMA R,IMANO Y,ITO W,et al. Appl Phys Lett[J],2006,88(19):192513.
[38] OIKAWA K,OTA T,OHMORI T,et al. Appl Phys Lett[J],2002,81(27):5201-5203.
[39] OIKAWA K,WULFF L,IIJIMA T,et al. Appl Phys Lett[J],2001,79(20):3290-3292.
[40] MA Y,YANG S,LIU Y,et al. Acta Mater[J],2009,57(11):3232-3241.
[41] SHEN A,SUN W,ZHAO D,et al. Phys Lett a[J],2018,382(39):2876-2879.
[42] LI Y,XIN Y,JIANG C,et al. Scripta Mater[J],2004,51(9):849-852.
[43] ZHANG X,SUI J,ZHENG X,et al. J Alloy Compd[J],2013,557:60-66.
[44] ZHANG X,SUI J,YU Z,et al. J Alloy Compd[J],2011,509(31):8032-8037.
[45] DONG G F,ZHANG H J,ZHANG X L,et al. Mater Sci Tech-Lond[J],2014,28(11):1332-1336.
[46] TAN C,ZHANG K,TIAN X,et al. J Alloy Compd[J],2017,692:288-293.
[47] LI H,MENG X,CAI W. Mater Sci Eng: A[J],2018,725:359-363.
[48] TIAN X,ZHANG K,TAN C,et al. Crystals[J],2018,8(6):247.
[49] SHEN Q,ZHAO D,SUN W,et al. J Alloy Compd[J],2017,696:538-542.
[50] WU Y,WANG J,JIANG C,et al. Mater Sci Eng: A[J],2015,646:288-293.
[51] LEE J,OH Y,EUH K,et al. Met Mater Int[J],2009,15(3):459-463.
[52] TSUCHIYA K,TSUTSUMI A,OHTSUKA H,et al. Mater Sci Eng: A[J],2004,378(1-2):370-376.
[53] GAO L,GAO Z Y,CAI W,et al. Mater Sci Eng: A[J],2006,438-440:1077-1080.
[54] GAO L,SUI J H,CAI W,et al. Solid State Commun[J],2009,149(5-6):257-260.
[55] GAO L,DONG G F,GAO Z Y,et al. J Alloy Compd[J],2012,520:281-286.
[56] CAI W,GAO L,LIU A L,et al. Scripta Mater[J],2007,57(7):659-662.
[57] SUI J,ZHANG X,GAO L,et al. J Alloy Compd[J],2011,509(35):8692-8699.
[58] NONG N V,TAI L T,HUY N T,et al. Mater Sci Eng: B[J],2011,176(16):1322-1325.
[59] PRUSIK K,MATYJA E,ZUBKO M,et al. Acta Phys Pol a[J],2016,130(4):1023-1025.
[60] AYDOGDU Y,TURABI A S,KOK M,et al. Applied Physics A[J],2014,117(4):2073-2078.
[61] ZHANG X,LIU Q,ZENG X,et al. Intermetallics[J],2016,68:113-117.
[62] BARMAN R,KAUR D. Vacuum[J],2015,120:22-26.
[63] YANG Z,CONG D Y,SUN X M,et al. Acta Mater[J],2017,127:33-42.
[64] YANG Z,CONG D,YUAN Y,et al. Mater Res Lett[J],2019,7(4):137-144.
[65] CONG D Y,HUANG L,HARDY V,et al. Acta Mater[J],2018,146:142-151.
[66] WANG Y,CHOO H. Acta Mater[J],2014,81:83-97.
[67] LI Z,LI Z,YANG J,et al. Scripta Mater[J],2019,162:486-491.
[68] HUANG Y J,HU Q D,LIU J,et al. Acta Mater[J],2013,61(15):5702-5712.
[69] HUANG Y J,HU Q D,BRUNO N M,et al. Scripta Mater[J],2015,105:42-45.
[70] HUANG Y J,HU Q D,BRUNO N,et al. Mater Lett[J],2014,114:11-14.
[71] MILL?N-SOLSONA R,STERN-TAULATS E,VIVES E,et al. Appl Phys Lett[J],2014,105(24):241901.
[72] ZHAO D,LIU J,CHEN X,et al. Acta Mater[J],2017,133:217-223.
[73] ZHAO D,LIU J,FENG Y,et al. Appl Phys Lett[J],2017,110(2):021906.
[74] LU B,SONG M,ZHOU Z,et al. J Alloy Compd[J],2019,785:1023-1029.
[75] LU B,XIAO F,YAN A,et al. Appl Phys Lett[J],2014,105(16):161905.
[76] CUI J,WU Y,MUEHLBAUER J,et al. Appl Phys Lett[J],2012,101(7):073904.
[77] BECHTOLD C,CHLUBA C,LIMA DE MIRANDA R,et al. Appl Phys Lett[J],2012,101(9):091903.
[78] MA?OSA L,JARQUE-FARNOS S,VIVES E,et al. Appl Phys Lett[J],2013,103(21):211904.
[79] XIAO F,FUKUDA T,KAKESHITA T. Appl Phys Lett[J],2013,102(16):161914.
[80] HERN?NDEZ-NAVARRO F,CAMARILLO-GARCIA J,AGUILAR-ORTIZ C,et al. Appl Phys Lett[J],2018,112(16):164101.
[81] DUNAND D C,M?LLNER P. Adv Mater[J],2011,23(2):216-232.
[82] UELAND S M,CHEN Y,SCHUH C A. Adv Funct Mater[J],2012,22(10):2094-2099.
[83] ZHUKOV A,GARCIA C,ILYN M,et al. J Magn Magn Mater[J],2012,324(21):3558-3562.
[84] ZHUKOV A,RODIONOVA V,ILYN M,et al. J Alloy Compd[J],2013,575:73-79.
[85] ZHUKOVA V,CHERNENKO V,IPATOV M,et al. IEEE T Magn[J],2015,51(11):1-4.
[86] ZHUKOVA V,IPATOV M,GRANOVSKY A,et al. J Appl Phys[J],2014,115(17):17A939.
[87] ZHUKOVA V,RODIONOVA V,FETISOV L,et al. Ieee T Magn[J],2014,50(11):1-4.
[88] ZHANG Y,LI M,WANG Y D,et al. Adv Eng Mater[J],2014,16(8):955-960.
[89] GLOCK S,ZHANG X X,KUCZA N J,et al. Composites Part A: Applied Science and Manufacturing[J],2014,63:68-75.
[90] LIU D M,CONG D Y,SUN X M,et al. J Alloy Compd[J],2017,728:655-658.
[91] DING Z Y,ZHU J,ZHANG X Z,et al. Journal of Physics D: Applied Physics[J],2017,50(9):095303
[92] LI F Q,QU Y H,YAN H L,et al. Appl Phys Lett[J],2018,113(11):112402.
[93] FENG Y,CHEN H,GAO L,et al. Mater Charact[J],2016,122:170-176.
[94] HERNANDO B,S?NCHEZ LLAMAZARES J L,PRIDA V M,et al. Appl Phys Lett[J],2009,94(22):222502.
[95] AKKERA H S,SINGH I,KAUR D. J Alloy Compd[J],2015,642:53-62.
[96] WEI Z Y,LIU E K,CHEN J H,et al. Appl Phys Lett[J],2015,107(2):022406.
[97] WEI Z Y,LIU E K,LI Y,et al. Appl Phys Lett[J],2016,109(7):071904.
[98] WEI Z Y,SUN W,SHEN Q,et al. Appl Phys Lett[J],2019,114(10):101903.
[99] SHEN Y,SUN W,WEI Z Y,et al. Scripta Mater[J],2019,163:14-18.
[100] ZHOU M,LI Y S,ZHANG C,et al. Chin. Phys. B[J],2019,27(10):106501.
[101] AZNAR A,GR?CIA-CONDAL A,PLANES A,et al. Phys Rev Mater[J],2019,3(4) :044406.
[102] SHEN Y,WEI Z,SUN W,et al. Acta Mater[J],2020,188:677-685.
备注/Memo
- 备注/Memo:
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_______________________________
收稿日期:2021-**-**基金项目:国家自然科学基金资助项目(51701052)
更新日期/Last Update:
2023-10-25