ライフサイエンスコーパス: ductility

1 hly organized, porous structure of increased ductility.

2 h an outstanding combination of strength and ductility.

3 e expense of other important properties like ductility.

4 often interpreted as the reason for improved ductility.

5 g of the metastable phase produces increased ductility.

6 or by cold working with the expense of their ductility.

7 the future to design new alloys with higher ductility.

8 e material can be doubled at no reduction in ductility.

9 h or high strength but significantly reduced ductility.

10 ic glass heterostructures to achieve tensile ductility.

11 eld strength alloy without sacrificing alloy ductility.

12 ercise in compromise between hardness versus ductility.

13 uch conflicting qualities as brittleness and ductility.

14 new avenues for improving their strength and ductility.

15 leness or an apparent loss of useful tensile ductility.

16 localization, resulting in near-zero tensile ductility.

17 ighest strain hardening and the best tensile ductility.

18 s a promising route to enhance the w-phase's ductility.

19 al increases in strength, work hardening and ductility.

20 ture have superior strength but usually poor ductility.

21 without seriously compromising their tensile ductility.

22 yield strength, ultimate tensile stress and ductility.

23 s, instigating crack initiation that hampers ductility.

24 tions(8-11), such obstacles tend to decrease ductility.

25 treatment improve strength at the expense of ductility.

26 n enhanced strength without apparent loss of ductility.

27 ilization due to their balanced strength and ductility.

28 ase transformation, to optimize strength and ductility.

29 ngly enhances both the ultimate strength and ductility.

30 arden alloys, yet, it often deteriorates the ductility.

31 unt of work hardening available, and thereby ductility.

32 Smaller nucleation sizes imply lower ductility.

33 ir superior ionic conductivity and excellent ductility.

34 in a concrete matrix to enhance strength and ductility.

35 sters acting as soft fillers to increase the ductility.

36 rapidly order metallic glasses according to ductility.

37 nfirming the solids mechanical stability and ductility.

38 to improved work hardening and large tensile ductility.

39 s (Al-RHEAs) demonstrating high strength and ductility.

40 ardening results into an undesirable loss of ductility.

41 t than dose on post-irradiation strength and ductility.

42 hanical properties in terms of stiffness and ductility.

43 e materials with high ionic conductivity and ductility.

44 favorited industrially as it only decreases ductility.

45 achieving properties including strength and ductility.

46 ing capability that promotes uniform tensile ductility.

47 y and storage stability while retaining high ductility.

48 ut compromising strain hardening and tensile ductility.

49 n, twin transmission is relevant to material ductility.

50 erials have high strength and relatively low ductility.

51 g to a simultaneous increase in strength and ductility.

52 with similar composition, yet, at identical ductility.

53 nergy, strengthen alloys without sacrificing ductility.

54 of metallic materials while preserving their ductility.

55 iphase crystalline solid solutions with high ductility.

56 complements related studies of strength and ductility.

57 f crystalline materials such as strength and ductility.

58 rials, which often result in reduced surface ductility.

59 bic (fcc) structure can exhibit high tensile ductility(1,2) and excellent toughness(2,3), but their r

60 The fabricated B(4)C beams exhibit a high ductility (~26.8%) at room temperature, a characteristic

61 t enhancement of yield strength (+ 145%) and ductility (+ 28%) without post-treatment.

62 er additive manufacturing often have limited ductility(3).

63 The excellent combination of T4 ductility (31%), T4 formability (7.8 mm) and T6 yield st

64 h both high tensile strength (13-24 MPa) and ductility (348 % strain at break) were prepared, along w

65 50 MPa) concurrent with high uniform tensile ductility (~35%).

66 nsile deformation, leading to a high tensile ductility--65% elongation to failure, and 30% uniform el

67 nsile strength (~2.3 GPa), and large uniform ductility (~7.0%) into the TiZr-based alloy.

68 eels typically come at the expense of useful ductility, a dilemma known as strength-ductility trade-o

69 a strength of up to 2.2 gigapascals and good ductility (about 8.2 per cent).

70 l combination of ultrahigh strength and high ductility, along with increased strain-rate sensitivity.

71 On the other hand, Ti increases ductility and [Formula: see text].

72 tions in polycarbonate, a material with high ductility and a large Fracture Process Zone (FPZ).

73 ify valence electron count domains for alloy ductility and brittleness with the explanation from dens

74 However, the effect of small size on ductility and creep of silicon remains elusive.

75 al understanding of the origins of intrinsic ductility and establish an electronic structure-based fr

76 ow substantial fracture toughness, they lack ductility and fail in an apparently brittle manner in un

77 echanical performance such as high strength, ductility and formability at room temperature (RT) are d

78 The ductility and formability of these materials is signific

79 differs greatly, leading to relatively poor ductility and formability.

80 atures but suffer from extremely low tensile ductility and fracture toughness.

81 However, the concurrent optimization of ductility and high-temperature properties remains a sign

82 tures while more silk fibre acts to increase ductility and impact strength.

83 al alloys which have significantly increased ductility and impact toughness, resulting from the ducti

84 strength to the caprock, contributing to its ductility and increased resistance to fracture.

85 well established even though they determine ductility and influence strengthening.

86 s that flow is delocalized, enhances tensile ductility and inhibits catastrophic mechanical failure(1

87 ribute, since an intrinsic lack of strength, ductility and low melting temperature severely restricts

88 ty of CTBs in strengthening, maintaining the ductility and minimizing the electron scattering is well

89 ng in Aluminium-5XXX alloys leads to reduced ductility and plastic instabilities at room temperature,

90 Mechanical studies confirm good ductility and resilience under repeated loading, while t

91 tests reveal that the BCANs exhibit enhanced ductility and strain hardening capability compared to bo

92 that we can create Ti-alloys with both good ductility and strength by tailoring w precipitates' comp

93 Our findings demonstrate how ductility and strength can be controlled through the rat

94 ic (FCC) structure is noteworthy because its ductility and strength increase with decreasing temperat

95 Here, we present an approach to enhance the ductility and strength of a medium-entropy alloy (MEA) f

96 isplacive deformation mechanisms, maximizing ductility and strength simultaneously in nanoscale mater

97 or mechanical behaviors (high strength, high ductility and superelasticity) and novel physical proper

98 s physical insights into the origins of high ductility and superior reversibility of hybrid CNT struc

99 Dislocation activity is critical to ductility and the mechanical strength of metals.

100 son's ratio and densification, connectivity, ductility and the toughness of solids; and their associa

101 fforded exceptional combination of strength, ductility and toughness for the nanofibrillar polymer co

102 Producing high strength, ductility and toughness is difficult, because inhibiting

103 m(1/2); at cryogenic temperatures strength, ductility and toughness of the CrCoNi alloy improve to s

104 one of the highest combinations of strength, ductility and toughness on record.

105 These polymers show enhanced ductility and toughness relative to polymers of pure rac

106 of two O-carboxyanhydrides exhibited better ductility and toughness than their corresponding homopol

107 and compress, thereby enhancing the scale's ductility and toughness to prevent fracture.

108 serving as a continuous source of strength, ductility and toughness.

109 typically comes at the cost of lowering the ductility and vice-versa, referred to as the strength-du

110 nstituent phases, and transformation-induced ductility and work-hardening capability are successfully

111 lectronic conductivity, mechanical adhesion, ductility, and electrolyte uptake.

112 with combinations of high strength, tensile ductility, and excellent fracture toughness.

113 The exceptional strength, ductility, and fatigue performance reported in this pape

114 deformation, affects fracture toughness and ductility, and is an important engineering material prop

115 to our understanding of plastic deformation, ductility, and mechanical strength of crystalline materi

116 f the polymer greatly improves the adhesion, ductility, and more importantly, the electrolyte uptake

117 groups on the diameter, length, composition, ductility, and oxidation of the produced NWs is discusse

118 he oxidation enhances the aluminium nanowire ductility, and the oxide shell exhibits superplastic beh

119 s of plastic deformation, strengthening, and ductility, and these complications pose significant chal

120 holds of the composites, enhancing strength, ductility, and toughness of the composites by adding sma

121 echanical properties including toughness and ductility, and unprecedented spatio-temporally controlle

122 eneously with much lower strength but better ductility; and also show strengthening in tension but we

123 l) have large magnetostriction and excellent ductility; and they are very promising rare-earth free m

124 gth levels of approximately 1 GPa, excellent ductility ( approximately 60-70%) and exceptional fractu

125 Combinations of high strength and ductility are hard to attain in metals.

126 efractory alloys with ultrahigh strength and ductility are in demand for a wide range of critical app

127 The combination of high strength and good ductility are very desirable for advanced structural and

128 The large tensile ductility arises owing to the high work-hardening capabi

129 inite-element implementation, to predict the ductility as a function of temperature and strain rate i

130 lticomponent high-entropy alloys (HEAs) lose ductility as they gain strength.

131 n strategy significantly enhances structural ductility, as reflected by notable reductions in pier-to

132 crease in bone strength and increase in bone ductility associated with chronic inflammation and GC th

133 ons; however, its use is limited by its poor ductility at low temperatures.

134 ing to their solubility in water and extreme ductility at raised temperatures (above approximately 12

135 e these excellent mechanical properties, low ductility at room temperature and poor microstructural s

136 ameters, predicts the observed steep drop in ductility at room temperature, which can be directly att

137 stalline materials often exhibit low tensile ductility at room temperature, which limits their practi

138 rare-earth intermetallic compounds with high ductility at room temperature.

139 s with excellent combination of strength and ductility, but also has great implications on overcoming

140 ded to lower [Formula: see text] and enhance ductility, but still retain enough Cr to maintain high m

141 and planar fault boundaries that enhance the ductility, but this has not been verified.

142 by 30 degrees C), yield stress (by 1.5 MPa), ductility (by 3x), and lower depolymerization temperatur

143 s strategy of interplay between strength and ductility can be achieved with sacrificial bonds in an a

144 Ductility can be increased by increasing the nucleation

145 It is shown that the tension ductility can range from near zero percent to over ten p

146 taneously demonstrate high strength and high ductility, characteristics that are usually thought to b

147 Owing to superior strength-ductility combination and great potential for applicatio

148 to mixtures of these polyolefins results in ductility comparable to the pure materials.

149 exhibits outstanding high strength and high ductility compared to other dilute Mg alloys.

150 lly designed HEAs with enhanced strength and ductility compared with other extensively studied CoCrNi

151 g material, leading to dramatically improved ductility compared with the untreated blends, along with

152 Alloys with higher strength and ductility could alleviate some of these concerns by redu

153 ies of intermetallics and derived a separate ductility criterion based on the difference between two

154 Ductility-dip cracking in Ni-based superalloy, resulting

155 onal space, enabling an efficient mapping of ductility directly from composition.

156 This combined increase in strength and ductility distinguishes the TRIP-DP-HEA alloy from other

157 Here, we unveiled the remarkable tensile ductility driven by vacancies in boron carbide (B(4)C).

158 However, they usually suffer from low ductility due to premature plastic instability by source

159 tical for metallic materials to achieve high ductility during plastic deformation.

160 the percolation theory that the compressive ductility, ec, can reach the maximum value at the interm

161 mechanical strength, while maintaining good ductility, electrical conductivity and thermal stability

162 es, while below the critical swim force, the ductility enhancement is caused by an increase of gel st

163 ical heterogeneity, which offers a means for ductility enhancement, damage evolution and toughening.

164 ents a promising way for improving gelatin's ductility, enhancing its potential for food-related and

165 BMG composites with room-temperature tensile ductility exceeding 10 per cent, yield strengths of 1.2-

166 perature, tensile strength, tensile modulus, ductility, flexural strength, and Izod impact energy.

167 gth and ductility, with a 6-fold increase in ductility for a Ti-6Al-0.3 O alloy as compared to a Ti-0

168 Our study demonstrates a much higher ductility for an amorphous oxide at low temperature than

169 B in 10 to 90 wt % dramatically enhances its ductility from ~5 % to 95-450 % and optical clarity from

170 d stress (~900 MPa) with appreciable tensile ductility (>20%), via annealing at 700 degrees C.

171 ving an optimal balance between strength and ductility in advanced engineering materials has long bee

172 The actualization of high strength and ductility in alloys, in addition to providing strong, fo

173 base material, and the weld joint shows high ductility in bending which is accomplished through the o

174 As a commonly used method to enhance the ductility in bulk metallic glasses (BMGs), the introduct

175 e molecular basis of centrosome strength and ductility in C. elegans embryos.

176 However, achieving tensile ductility in covalent materials remains challenging and

177 rt the observation of an exceptional tensile ductility in crystalline copper/copper-zirconium glass n

178 roviding insight into how one could increase ductility in glassy materials.

179 des, can simultaneously enhance strength and ductility in high-entropy alloys.

180 listic penetrators, spacecraft shielding and ductility in high-performance ceramics.

181 etastable disorder or doping to achieve some ductility in intermetallic compounds at room temperature

182 d plasticity (TRIP) leads to enhancements in ductility in low stacking fault energy (SFE) alloys, how

183 ound to overcome the paradox of strength and ductility in metals benefiting from their unique deforma

184 means to enhance yield strength and tensile ductility in metals, nanotwinned metals generally fail w

185 anner, and observed a systematic increase in ductility in samples quenched under increasingly higher

186 te sensitivity and elucidating the origin of ductility in terms of the interactions of dislocations w

187 Retaining ductility in these metals, however, has proven difficult

188 generates high strength, work hardening and ductility, including the easy motion of Shockley partial

189 spects provide guidance in designing tensile ductility into metallic glasses.

190 g tough adhesives with superior strength and ductility is challenging yet highly sought-after.

191 Ductility is critical for preventing materials catastrop

192 The ductility is improved significantly for all shear critic

193 nsile yield strength is enhanced by ~75% and ductility is substantially improved by ~164% with additi

194 t is thought that one reason for the lack of ductility is that the development of - double twins (DTW

195 The increase in surface ductility is unexpected because it is the opposite patte

196 high strength, substantial deformability and ductility, large elastic limit and low density represent

197 ing-induced plasticity and breaking strength-ductility limits in nanostructured BCC metals.

198 l mechanisms for increasing strength lead to ductility loss, an effect referred to as the strength-du

199 e a balance of properties including moderate ductility, low density, and the necessary formability.

200 reminiscent of the "intermediate temperature ductility minimum" observed in polycrystalline metals.

201 o an exceptional combination of strength and ductility not possible from pure Mg.

202 occurs in unloading, which expounds the high ductility observed in the experiment.

203 tallic interfaces accounts for the extensive ductility observed.

204 printed and post-processed forms and tensile ductilities of greater than 13% at room temperature.

205 ltrahigh strength of 2.15 GPa with a tensile ductility of 15% at ambient temperature, with a high yie

206 ed to around 710 megapascals, with a uniform ductility of 45 per cent and a tensile strength of aroun

207 a high strength of 980 MPa and an ultrahigh ductility of 58% at fracture.

208 yield strength of 1074 MPa with a reasonable ductility of 8%.

209 The microstructure and tension ductility of a series of Ti-based bulk metallic glass ma

210 le strengths of approximately 1 GPa, tensile ductility of approximately 2-3 per cent, and an enhanced

211 and offers opportunities for controlling the ductility of BMG alloys.

212 material property that controls strength and ductility of crystals.

213 ides an easy and effective way to extend the ductility of intrinsically-brittle BMGs, opening up wide

214 Unfortunately, the ductility of magnesium alloys is usually limited.

215 e for widespread applications is the limited ductility of magnesium, which has been attributed to [Fo

216 which is very encouraging for improving the ductility of medium-carbon steels.

217 Simultaneously enhancing strength and ductility of metals and alloys has been a tremendous cha

218 ome the inherent limitations in strength and ductility of Mg alloys.

219 We postulate that the ductility of nacre can be limited by eliminating tablet

220 We attribute the relatively high ductility of nano-twinned copper to the hardening of twi

221 f the microscopic structure underpinning the ductility of silica glass will not only pave the way tow

222 we develop a theory to quantify the kinetic ductility of single molecules from force spectroscopy ex

223 ltaneous improvement of strength and tensile ductility of structural metallic materials.

224 aterial properties associated with increased ductility of strut surfaces.

225 is probably related to temperature-dependent ductility of the crust at shallow depths (7 8 km on Euro

226 crimping explain the unexpected strength and ductility of the current BVS and point the way to thinne

227 gths of the developed mixtures, however, the ductility of the mixtures was improved with the incorpor

228 seismic event, the slit zones increased the ductility of the shaft, reduced stress concentration in

229 ation, thus leading to enhanced strength and ductility of the TRIP-assisted dual-phase HEA engineered

230 The high strength and high ductility of this 3-element nanocomposite material puts

231 C treatment in the TNF-Tg mice increased the ductility of tibiae under torsional loading.

232 or aluminum has a deleterious effect on the ductility of titanium alloys.

233 e, substitutional aluminum will decrease the ductility of titanium at low-oxygen concentrations.

234 oxygen can severely deteriorate the tensile ductility of titanium, particularly at cryogenic tempera

235 In the present work, we show that the ductility of Zr-based BMGs with nearly zero plasticity i

236 ultimate tensile strength was 1165 MPa with ductility of ~18% and ultimate compressive strength was

237 ably an increased yield stress and decreased ductility, often accompanied by plastic flow localizatio

238 However, ductility or formability of metallic alloys at RT are ge

239 wed significant improvements in strength and ductility over the baseline NiCoCr.

240 ctility, which breaks the so-called strength-ductility paradox.

241 cation vibrational properties, and intrinsic ductility parameters derived from unstable stacking faul

242 For ductility prediction, we adopt the framework established

243 te can invoke simultaneous high strength and ductility, producing an affordable, biocompatible Mg all

244 l materials requiring both high strength and ductility, properties that are often mutually exclusive.

245 ransus temperature, [Formula: see text], and ductility (quantified by peak true strain, [Formula: see

246 hotomy to introduce a high strength and high ductility RAFM steel, produced by a modified thermomecha

247 asures to enhance strength typically lead to ductility reduction due to their inverse correlation, na

248 or impede the motion of dislocations involve ductility reduction.

249 ping alloys with both ultrahigh strength and ductility remains a formidable scientific challenge, pri

250 bility is limited by their near-zero tensile ductility resulting from work-softening and shear locali

251 proportion of metal carbides, while the high ductility results from a high mobile dislocation density

252 t twin structure can cause strengthening and ductility retention, and how sequential torsion and tens

253 excellent properties such as stretchability, ductility, shear-thinning, and thixotropy.

254 In particular, their poor ductility significantly impedes their industrial applica

255 0 times as that of single crystals, and with ductility simultaneously.

256 ndow our material with an effective strength-ductility-strain hardening combination.

257 sive properties in metals including strength-ductility, strength-thermal stability, and strength-elec

258 ning, as a general strategy towards strength-ductility synergy beyond current benchmark ranges.

259 Realizing improved strength-ductility synergy in eutectic alloys acting as in situ c

260 cal design principle to enhance the strength-ductility synergy in HEAs.

261 loys with TRIP/TWIP for an enhanced strength-ductility synergy.

262 allenges for phase control and high strength-ductility synergy.

263 ing, thereby bestowing improved strength and ductility than composites with discrete reinforcements.

264 lly metallic and organic materials with good ductility that are tolerant of complex deformation.

265 a combination of yield strength and tensile ductility that surpasses that of conventional 316L steel

266 r simultaneously achieving high strength and ductility, thereby circumventing this well-known trade-o

267 he possible means of optimizing strength and ductility through interfacial engineering.

268 potential to achieve high strength and high ductility through manipulation of their microstructures.

269 1 and SPD-2 respectively confer strength and ductility to the centrosome scaffold so that it can resi

270 se monocarbides, while maintaining a similar ductility to the least brittle monocarbide (TaC) during

271 localization offers flaw tolerance, allowing ductility to win over fracture.

272 rovides upward of 18% improvement in strain (ductility) to the composite and eliminates brittle fract

273 fabricate steels with high strength and high ductility (toughness).

274 s of mechanical properties such as strength, ductility, toughness, elasticity and requirements for pr

275 To understand how the strength-ductility trade-off can be defeated, we apply in situ, a

276 The strength-ductility trade-off has been a long-standing dilemma in

277 ticity (TRIP/TWIP) can overcome the strength-ductility trade-off in structural materials.

278 It is shown that this evasion of strength-ductility trade-off is due to the formation of a gradien

279 The results not only break the strength-ductility trade-off of conventional SLM alloys, but also

280 have attempted to evade this strength versus ductility trade-off, but the paradox persists.

281 h of twinning-induced plasticity steel at no ductility trade-off.

282 and vice-versa, referred to as the strength-ductility trade-off.

283 seful ductility, a dilemma known as strength-ductility trade-off.

284 loss, an effect referred to as the strength-ductility trade-off.

285 e environments, as well as overcome strength-ductility trade-offs and provide overarching design stra

286 ave been introduced to overcome the strength-ductility tradeoff in face-centered cubic (FCC) high-ent

287 ons on overcoming the long-standing strength-ductility tradeoff of metallic materials in general.

288 enge, primarily due to the inherent strength-ductility tradeoff.

289 hows that the trade-off between strength and ductility typically observed for metallic materials is s

290 dulus, indicators of yield strain and tissue ductility using a mixed model.

291 Remarkable tensile ductility was first obtained in an in-situ Ti-based bulk

292 degrees C aging also demonstrates remarkable ductility when deformed at elevated temperatures.

293 r of four while also substantially improving ductility, which breaks the so-called strength-ductility

294 imultaneously possess high strength and high ductility, which have potential industrial applications.

295 neous enhancement of mechanical strength and ductility, which is quite challenging to achieve by conv

296 only provide strength but also contribute to ductility, which is very encouraging for improving the d

297 d O substantially improves both strength and ductility, with a 6-fold increase in ductility for a Ti-

298 in strain-rate sensitivity, as a measure of ductility, with Pd content and thermal history is sugges

299 sought goal in metallic glasses is to impart ductility without conceding their strength and elastic l

300 d the bimodal microstructure, which improves ductility without impairing strength.