ライフサイエンスコーパス: solidification

1 en material into the desired geometry before solidification.

2 nder pressure into desired forms-followed by solidification.

3 hematically modeled, before subsequent shell solidification.

4 ormation, combination/alloying, shaping, and solidification.

5 coherent growth model of irregular eutectic solidification.

6 in the magnetic field assisting directional solidification.

7 emerge from colloidal templating of eutectic solidification.

8 inter-dendritic segregation of Ag during re-solidification.

9 al volume (>10,000 mm(3)) during melting and solidification.

10 anges of composition/temperature for primary solidification.

11 ugh a significant period of carbonatite melt solidification.

12 hy has enabled real-time glimpses into metal solidification.

13 tallized in the latter stages of magma ocean solidification.

14 oys that vitrify with remarkable ease during solidification.

15 t evidence for the role of convection in the solidification and differentiation of a simple magma she

16 We develop a model for the dynamic solidification and its effect on the surrounding suspens

17 fill-in-the-gaps in our understanding of the solidification and melting pathways of quasicrystals, we

18 alise real time in-situ visualisation of the solidification and the measurement of solidified shell t

19 on energy barrier for phase-change materials solidification and to conserve thermal energy in the mat

20 challenges due to its high viscosity, rapid solidification, and its impact on immunohistochemical an

21 g melt pool dynamics, powder ejection, rapid solidification, and phase transformation, can be probed

22 y to phase transitions during binary-mixture solidification, and validated it using drug perturbation

23 These particles exhibit stability against solidification at ambient conditions.

24 e the ramifications of the classic models of solidification at the microscale, and demonstrate suppre

25 DMSO works as a cryogenic protector avoiding solidification at the temperatures used to block the syn

26 Effective control of melting and solidification behaviours of materials is significant fo

27 er, nanoparticle-induced unusual melting and solidification behaviours of metals are reported that ef

28 weak, stress heterogeneities frozen-in upon solidification can still partially relax through elastic

29 the asymmetric freezing dynamics with inward solidification causing not fully frozen mass to be displ

30 ntual shutdown of the magnetic field as core solidification completed.

31 ng, casting and injection moulding, in which solidification cracking and hot tearing are also common

32 To elucidate the failure mechanisms, solidification cracking during arc welding of steel are

33 Solidification cracking is a key phenomenon associated w

34 ed may have once been ice rafts or the rocky solidification crust of a large lava flow.

35 Solidification-driven convection was probably common amo

36 cing nanoparticles of nucleants that control solidification during additive manufacturing.

37 These phenomena include solidification during rapid impact, as well as strong sh

38 ely accepted that volumetric contraction and solidification during the polymerization process of rest

39 itively manufactured because the melting and solidification dynamics during the printing process lead

40 High strength is attributed to solidification-enabled cellular structures, low-angle gr

41 loped process of temperature-regulated rapid solidification followed by sintering.

42 ion is preferred, but this requires hydrogel solidification from a low viscosity solution to occur in

43 depending on the symmetry of the propagating solidification front and its velocity, such as axial or

44 he flow, it was actually formed in the upper solidification front and was transported down in plumes

45 stresses originate from an impact-generated solidification front that transforms an initially compre

46 peed imaging confirms a technically relevant solidification front velocity and cooling rate of 10.3 m

47 us; magnetite (Fe3O4) forms at the oxidation-solidification front with a morphology suggestive of a L

48 rn formation of a moving boundary, such as a solidification front.

49 t only provide a deeper understanding of the solidification growth patterns during the additive manuf

50 elds, temperature gradients, and directional solidification have also been demonstrated to induce ori

51 hieved by vitrification, which is defined as solidification in an amorphous glassy state that obviate

52 g the key challenges to our understanding of solidification in the glass transition is that it is acc

53 tern formation is that of irregular eutectic solidification, in which the solid-liquid interface is n

54 The rapid solidification induced softening of colloidal glass is o

55 revious work showed that this impact-induced solidification involves rapidly moving jamming fronts; h

56 Imaging metal solidification is a great example for which there is no

57 ect the formation of reinforced phase during solidification is crucial to tailor the structure and th

58 g occurs in the steady state, impact-induced solidification is transient.

59 lution of the configurational entropy during solidification, is undertaken in the present study using

60 apes due to their rotation mid-flight before solidification, just as we observe here.

61 ot only have impacts on existing melting and solidification manufacturing processes, such as laser we

62 d-liquid microextraction method based on the solidification of a floating organic drop (DLLME-SFO) wa

63 quid microextraction techniques based on the solidification of a floating organic drop (VA-DLLME-SFO)

64 s a direct consequence of volume-constrained solidification of a material undergoing anomalous expans

65 at the cell shapes formed during directional solidification of alloys can be described by the form of

66 ate tectonics, and mantle overturn following solidification of an early magma ocean.

67 that magnetic activity driven by progressive solidification of an inner core is consistent with our m

68 ossibility of two-dimensional writing, rapid solidification of chains and methods to scale up chain p

69 explanation postulated for the transition is solidification of correlated motions in proteins below t

70 usion construct validation, cell growth, and solidification of embedding resins.

71 iquid-liquid microextraction method based on solidification of floating organic droplet (DLLME-SFO) w

72 hought to begin with differentiation through solidification of magma oceans many hundreds of kilometr

73 The discovery of the unusual melting and solidification of materials that contain nanoparticles w

74 ted zone (HAZ) size during local melting and solidification of materials.

75 Coalescence and solidification of nanoscale droplets results in formatio

76 rsive liquid-liquid microextraction based on solidification of organic drop: a fractional factorial a

77 erved important roles in the negotiation and solidification of social relationships, the integration

78 ructure during melting, reactive wetting and solidification of solder pastes on Cu-plated printed cir

79 Rather, disassembly or solidification of the actin cytoskeleton prior to incuba

80 c reactor, where the particles are formed by solidification of the carrier droplets.

81 transient states of nucleation, growth, and solidification of the complex.

82 Solidification of the endosperm in homozygous dsc1- muta

83 Pressure-induced solidification of the H2-SiH4 fluid shows a binary eutec

84 is induced by reversible, localized gel-like solidification of the membrane.

85 Primordial solidification of the Moon (or its uppermost layer) resu

86 reversible changes occurred culminating with solidification of the SAM film at the largest compressiv

87 hanism is proposed to be a process following solidification of the Zn liquid droplets, surface oxidat

88 ests freezing-in of crystal alignment during solidification or texturing by Maxwell stress as origins

89 e metastable states that are relevant to the solidification pathway of the molecule under interest.

90 um segregate unevenly during non-equilibrium solidification, presenting new fabrication challenges, a

91 g the speed of sound we demonstrate that the solidification proceeds without a detectable increase in

92 This continuous solidification process exhibits great diversity within e

93 by controlling the cooling rate of the laser solidification process has been presented.

94 , we shed light on this biological amorphous solidification process, demonstrating that the observed

95 The factors governing the spatiotemporal solidification process, including front position, profil

96 examine the changes of its inductance during solidification process.

97 SnO diskettes is suggested to result from a solidification process.

98 r the real time in-situ imaging of the metal solidification process.

99 99.0% concentricity and sphericity, and the solidification processing period was significantly reduc

100 Rapid solidification produces a unique ultra-fine microstructu

101 atively measured, and the slowly decrease in solidification rate during the relatively steady state c

102 a certain temperature gradient, the critical solidification rate first increases, then decreases, and

103 he magnetic field dependence of the critical solidification rate for the stability of liquid-solid in

104 effect of the magnetic field on the critical solidification rate is more pronounced at low than at hi

105 microstructure and mechanical properties on solidification rate is not well reported.

106 The solidification rate is quantitatively measured, and the

107 um strength was obtained at the intermediate solidification rate of 30 Cs(-1).

108 related to the microstructure variation with solidification rate.

109 , but a causal link between these motifs and solidification remains elusive.

110 This prolonged solidification requires the existence of a primitive thi

111 ve their effectiveness using a novel droplet solidification technique, and demonstrate an approach to

112 namic folding transition temperature and the solidification temperature based on the Lindemann criter

113 Solidification texture depends on the local heat flow di

114 Striking differences in the solidification textures of a nickel based alloy owing to

115 g, it also serves as a basis for customizing solidification textures which are important for properti

116 ues, we observe that if we increase the film solidification time the polymer develops a higher crysta

117 tals and reduces the undercooling needed for solidification to take place.

118 s offers a mild, spatiotemporally controlled solidification trigger.

119 The molten ink undergoes directional solidification upon printing on a cold substrate.

120 ssion of constitutional undercooling at high solidification velocities.

121 twins may nucleate in Si precipitates after solidification, which provides a different perspective t

122 esters accelerated early-stage cocoa butter solidification while suppressing later growth.