½éÉÜÁ˸ßÎÂÐÎ×´¼ÇÒäºÏ½ðÂíÊÏÌåת±äζȵÄÓ°ÏìÒòËؼ°ÆäÔÚʹÓùý³ÌÖжÔÐÔÄܵÄÒªÇó, ²¢×ÛÊöÁËîÑÄøîÙ/²¬¡¢ÄøîÑï¯/îþ¡¢ÄøÃÌïصȼ¸ÖÖÖ÷Òª¸ßÎÂÐÎ×´¼ÇÒäºÏ½ðµÄÑо¿½øÕ¹, ×îºó¶Ô½ñºóµÄÑо¿·½Ïò½øÐÐÁËÕ¹Íû¡£

ËùÊôÀ¸Ä¿

×ÛÊö¹ú¼Ò×ÔÈ»¿Æѧ»ù½ð×ÊÖúÏîÄ¿(51174251); ¿Æ¼¼²¿¡°973¡±¼Æ»®×ÊÖúÏîÄ¿(2011CB706604)

ÊÕ¸åÈÕÆÚ

2012/12/52013/10/7

×÷Õßµ¥Î»

×óË´¹ó:ÉϺ£½»Í¨´óѧ²ÄÁÏ¿ÆѧÓ빤³ÌѧԺ, ÉϺ£ 200240
½ðѧ¾ü:ÉϺ£½»Í¨´óѧ²ÄÁÏ¿ÆѧÓ빤³ÌѧԺ, ÉϺ£ 200240
½ðÃ÷½­:ÉϺ£½»Í¨´óѧ²ÄÁÏ¿ÆѧÓ빤³ÌѧԺ, ÉϺ£ 200240

±¸×¢

×óË´¹ó(1985-), ÄÐ, ºþÄϦµ×ÈË, ²©Ê¿Ñо¿Éú¡£

ÒýÓøÃÂÛÎÄ:

ZUO Shun-gui,JIN Xue-jun,JIN Ming-jiang.Research Progress in High Temperature Shape Memory Alloys[J].Materials for mechancial engineering,2014,38(1):1¡«5
×óË´¹ó,½ðѧ¾ü,½ðÃ÷½­.¸ßÎÂÐÎ×´¼ÇÒäºÏ½ðµÄÑо¿½øÕ¹[J].»úе¹¤³Ì²ÄÁÏ,2014,38(1):1¡«5

±»ÒýÇé¿ö:

¡¾1¡¿

ÖÜÕý´æ,¶Å½à,ÕÅÒåƽ,¹ËËÕâù,Ñîºé,ÑÏÓ½¡, "ÓÍ´ãNi₆₄Al₃₆ºÏ½ðµÄÄæÂíÊÏÌåÏà±ä",»úе¹¤³Ì²ÄÁÏ 38, 46-49(2014)

¡¾2¡¿

ÖìÉîÁÁ,¶­ºé²¨,ÕŹó»ª,ÎâÓîÁú,ÐÜêź½,ÕÔº£²¨, "µçÁ÷¶ÔNiTiCuÐÎ×´¼ÇÒäºÏ½ðË¿µçÈÈÇý¶¯ÌØÐÔµÄÓ°Ïì",»úе¹¤³Ì²ÄÁÏ 40, 16-18(2016)
²Î¿¼ÎÄÏ×

¡¾1¡¿

ZARINEJAD M, LIU Y. Dependence of transformation temperatures of NiTi-based shape-memory alloys on the number and concentration of valence electrons£ÛJ£Ý.Advanced Functional Materials,2008,18(18):2789-2794.

¡¾2¡¿

GOLBERG D, XU Y, MURAKAMI Y, et al. Characteristics of Ti50Pd30Ni20 high-temperature shape memory alloy£ÛJ£Ý.Intermetallics,1995,3:35-46.

¡¾3¡¿

ATLI K C, KARAMAN I, NOEBE R D, et al. Shape memory characteristics of Ti49.5Ni25Pd25Sc0.5 high-temperature shape memory alloy after severe plastic deformation£ÛJ£Ý.Acta Materialia,2011,59(12):4747-4760.

¡¾4¡¿

ATLI K C, KARAMAN I, NOEBE R D, et al. Improvement in the shape memory response of Ti50.5Ni24.5Pd25 high-temperature shape memory alloy with scandium microalloying£ÛJ£Ý.Metallurgical and Materials Transactions: A,2010,41(10):2485-2497.

¡¾5¡¿

SHIMIZU S, XU Y, OKUNISHI E, et al. Improvement of shape memory characteristics by precipitation-hardening of Ti-Pd-Ni alloys£ÛJ£Ý.Materials Letters,1998,34(1/2):23-29.

¡¾6¡¿

GOLDBERG D, XU Y, MURAKAMI Y, et al. Improvement of a Ti50Pd30Ni20 high temperature shape memory alloy by thermomechanical treatments£ÛJ£Ý.Scr Metall Mater,1994,30(10):1349-1354.

¡¾7¡¿

SAWAGUCHI T, SATO M, ISHIDA A. Microstructure and shape memory behavior of Ti51.2(Pd27.0Ni21.8) and Ti49.5(Pd28.5Ni22.0) thin films£ÛJ£Ý.Materials Science and Engineering:A,2002,332(1/2):47-55.

¡¾8¡¿

CUI J, CHU Y S, FAMODU O O, et al. Combinatorial search of thermoelastic shape-memory alloys with extremely small hysteresis width£ÛJ£Ý.Nature Materials,2006,5(4):286-290.

¡¾9¡¿

MENG X L, ZHENG Y F, WANG Z, et al. Shape memory properties of the Ti36Ni49Hf15 high temperature shape memory alloy£ÛJ£Ý.Materials Letters, 2000,45:128-32.

¡¾10¡¿

PU Z J, TSENG H K, WU K H. Martensite transformation and shape memory effect of NiTi-Zr high-temperature shape memory alloys£ÛC£Ý// Proc SPIE 2441.£ÛS.l£Ý:£Ûs.n.£Ý,1995:171.

¡¾11¡¿

MENG X L, CAI W, FU Y D, et al. Shape-memory behaviors in an aged Ni-rich TiNiHf high temperature shape-memory alloy£ÛJ£Ý.Intermetallics,2008,16(5):698-705.

¡¾12¡¿

YANG F, COUGHLIN D R, PHILLIPS P J, et al. Structure analysis of a precipitate phase in an Ni-rich high-temperature NiTiHf shape memory alloy£ÛJ£Ý.Acta Materialia,2013,61(9):3335-3346.

¡¾13¡¿

RUSSELL S, SCZERZENIE F. Engineering considerations in the application of NiTiHf and NiAl as practical high-temperature shape memory alloys£ÛJ£Ý.Proc Mater Rec Soc Symp,1995,360:455-460.

¡¾14¡¿

KIM H Y, TAKAFUMI J, NAM T, et al. Cold workability and shape memory properties of novel Ti-Ni-Hf-Nb high temperature shape memory alloys£ÛJ£Ý.Scripta Materialia,2011,65:846-849.

¡¾15¡¿

MENG X L, CAI W, LAU K T, et al. Phase transformation and microstructure of quaternary TiNiHfCu high temperature shape memory alloys£ÛJ£Ý.Intermetallics,2005,13(2):197-201.

¡¾16¡¿

PONS J, CHERNENKO V A, SANTAMARTA R, et al. Crystal structure of martensitic phases in Ni-Mn-Ga shape memory alloys£ÛJ£Ý.Acta Materialia,2000,48(12):3027-3038.

¡¾17¡¿

MA Y, JIANG C, LI Y, et al. Study of Ni50+xMn25Ga25-x(x=2-11) as high-temperature shape-memory alloys£ÛJ£Ý.Acta Materialia,2007,55(5):1533-1541.

¡¾18¡¿

XU H, MA Y, JIANG C. A high-temperature shape-memory alloy Ni54Mn25Ga21£ÛJ£Ý.Applied Physics Letters,2003,82(19):3206-3208.

¡¾19¡¿

MA Y Q, JIANG C B, FENG G, et al. Thermal stability of the Ni54Mn25Ga21 Heusler alloy with high temperature transformation£ÛJ£Ý.Scripta Materialia,2003,48(4):365-369.

¡¾20¡¿

TSUCHIYA K, TSUTSUMI A, OHTSUKA H, et al. Modification of Ni-Mn-Ga ferromagnetic shape memory alloy by addition of rare earth elements£ÛJ£Ý.Materials Science and Engineering:A,2004,378(1):370-376.

¡¾21¡¿

SUI J, GAO Z, YU Hui-ru, et al. Martensitic and magnetic transformations of Ni56Fe17Ga27-xCox high-temperature ferromagnetic shape memory alloys£ÛJ£Ý.Scripta Materialia,2008,59(8):874-877.

¡¾22¡¿

LI Y, XIN Y, JIANG C, et al. Shape memory effect of grain refined Ni54Mn25Ga21 alloy with high transformation temperature£ÛJ£Ý.Scripta Materialia,2004,51(9):849-852.

¡¾23¡¿

OTSUKA K, SAKAMOTO H, SHIMIZU K. Successive stress-induced martensitic transformations and associated transformation pseudoelasticity in Cu-Al-Ni alloys£ÛJ£Ý.Acta Metallurgica,1979;27:585-601.

¡¾24¡¿

ADACHI K, SHOJI K, HAMADA Y. Formation of Chi phases and origin of grain refinement effect in Cu-Al-Ni shape memory alloys added with titanium£ÛJ£Ý.ISIJ Int,1989,29(5):378-387.

¡¾25¡¿

MORRIS M A. High temperature properties of ductile Cu-Al-Ni shape memory alloys with boron additions£ÛJ£Ý.Acta Metallurgica et Materialia,1992,40(7):1573-1586.

¡¾26¡¿

P¦IR¦IZ-S¦BEZ R B, RECARTE V, N¦„M L, et al. Advanced shape memory alloys processed by powder metallurgy£ÛJ£Ý.Advanced Engineering Materials,2000,2(1/2):49-53.

¡¾27¡¿

DAGDELEN F, GOKHAN T, AYDOGDU A, et al. Effects of thermal treatments on transformation behaviour in shape memory Cu-Al-Ni alloys£ÛJ£Ý.Materials Letters,2003,57(5/6):1079-1085.

¡¾28¡¿

GAO Y, ZHU M, LAI J K L. Microstructure characterization and effect of thermal cycling and ageing on vanadium-doped Cu-Al-Ni-Mn high-temperature shape memory alloy£ÛJ£Ý.Journal of Materials Science,1998,33(14):3579-3584.

¡¾29¡¿

BUENCONSEJO P J S, KIM H Y, HOSODA H, et al. Shape memory behavior of Ti-Ta and its potential as a high-temperature shape memory alloy£ÛJ£Ý.Acta Materialia,2009,57(4):1068-1077.

¡¾30¡¿

BUENCONSEJO P J S, KIM H Y, MIYAZAKI S. Novel ¦Â-TiTaAl alloys with excellent cold workability and a stable high-temperature shape memory effect£ÛJ£Ý.Scripta Materialia,2011,64(12):1114-1117.

¡¾31¡¿

ZHENG X H, SUI J H, ZHANG X, et al. Thermal stability and high-temperature shape memory effect of Ti-Ta-Zr alloy£ÛJ£Ý.Scripta Materialia,2013,68(12):1008-1011.

¡¾32¡¿

FIRSTOV G S, KOVAL Y N, HUMBEECK J, et al. Martensitic transformation and shape memory effect in Ni3Ta: a novel high-temperature shape memory alloy£ÛJ£Ý.Materials Science and Engineering: A,2008,481/482:590-593.

¡¾33¡¿

LAI A, DU Z, GAN C L, et al. Shape memory and superelastic ceramics at small scales£ÛJ£Ý.Science,2013,341:1505-1508.

¡¾34¡¿

MA J, KARAMAN I, NOEBE R D. High temperature shape memory alloys£ÛJ£Ý.International Materials Reviews,2010,55(5):257-315.