ライフサイエンスコーパス: shape memory alloy

1 tion Ni(2)MnGa is a well known ferromagnetic shape-memory alloy.

2 ive compared to their metallic counterparts, shape memory alloys.

3 oss factor (up to 0.033) comparable to Ni-Ti shape memory alloys.

4 urized origami structures based on thin-film shape memory alloys.

5 e intervals of the deformation mechanisms of shape memory alloys.

6 ated with diffusionless phase transitions in shape-memory alloys.

7 can be reversible, such as those observed in shape-memory alloys.

8 Shape memory alloys(3)-including gum metals(4,5) and str

9 Examples are shape memory alloys and high strength steels, which toge

10 ve polymers ( > 1KV), low strain ( < 10%) of shape memory alloys and the need for external compressor

11 y combining two contrasting components: NiTi shape-memory alloy and Ag.

12 Additionally, the shape memory alloy can also "store" the magnetoelectric

13 metric Ni(2)MnGa Heusler alloy is a magnetic shape-memory alloy capable of reversible magnetic-field-

14 port on the discovery of an ultralow-fatigue shape memory alloy film system based on TiNiCu that allo

15 magnetically driven "mag-bot" that utilizes shape memory alloy-induced, thermoresponsive actuation a

16 twisted nanofiber yarns; thermally activated shape-memory alloys; ionic-polymer/metal composites; die

17 The introducing of the shape memory alloys may prevent such problem by taking t

18 artensite phase of shape memory and magnetic shape memory alloys (MSMAs) is believed to be a precurso

19 Functional shape memory alloys need to operate reversibly and repea

20 achieve shape morphing structures is through shape memory alloys or hydrogels.

21 A nickel-titanium shape memory alloy part was created with multiple shape-

22 ues of the order of those of widely deployed shape-memory alloys, paving the way for their use as via

23 f randomly-packed rod-like particles made of shape memory alloy (SMA), we exploit that shape recovery

24 ABSTARCT: Shape memory alloys (SMAs) have the ability to show larg

25 ajor obstacle to the functional stability of shape memory alloys (SMAs), especially for high temperat

26 ntegration of responsive materials including shape memory alloys (SMAs), piezoelectrics, dielectric e

27 Shape memory alloys (SMAs), such as Nitinol (i.e., NiTi)

28 s for many functional applications including shape memory alloys (SMAs), switches based on metal-insu

29 Shape-memory alloys (SMAs) are a unique class of metal a

30 e range of applications from fatigue life in shape-memory alloys (SMAs) to magnetism in multiferroic

31 th only a few lightweight actuators (such as shape-memory alloy springs), and do not need constant ac

32 ing L10-FePt films on pre-stretched NiTi(Nb) shape memory alloy substrates, steerable and nonvolatile

33 e propose a new design strategy that employs shape memory alloy to transcribe the "J-curve" mechanica

34 ions in natural and man-made materials, from shape-memory alloys to steel to planetary cores.

35 -range order in diverse systems ranging from shape-memory alloys to unconventional superconductors, a

36 Shape memory alloys undergo reversible transformations b

37 een nanowires and orientated martensite NiTi shape memory alloy, we developed an in-situ Nb nanowires

38 asurements revealed that these meta-magnetic shape memory alloys were capable of generating entropy c

39 ic transformations in NiCoMnIn meta-magnetic shape memory alloys were studied under constant and vary

40 y low thermal hysteresis (DeltaT) NiTi-based shape memory alloys, with Ti50.0Ni46.7Cu0.8Fe2.3Pd0.2 po