ライフサイエンスコーパス: alloy

1 elements have many isotopes (e.g., palladium alloys).

2 .g., natural polymers, plastics, steels, and alloys).

3 is the tellurium-poor WSe(2-2) (y) Te(2) (y) alloy.

4 e evolved in additively manufactured Ti6Al4V alloy.

5 formed from oxidation of a palladium-silver alloy.

6 tropy of fusion of the crystallized eutectic alloy.

7 (x: 0, 0.5, 1, and 1.5) complex concentrated alloy.

8 y, producing an affordable, biocompatible Mg alloy.

9 manium-rich regions of the silicon germanium alloy.

10 cales originated from Cr(0) in the cast iron alloy.

11 ort-range order in the CrCoNi medium-entropy alloy.

12 oined i-MAB, along with 16 disordered stable alloys.

13 om high-performance turbine blades to solder alloys.

14 ise interatomic distances rather than random alloys.

15 producing high-index single-crystal Cu-based alloys.

16 was studied in low rare earth concentration alloys.

17 body-centered cubic (bcc) variants of these alloys.

18 investigations of numerous new platforms and alloys.

19 se effect of TBs on the performance of these alloys.

20 iction and performance optimisation of these alloys.

21 ptional high temperature strength of similar alloys.

22 ructures of high-index metal foils and their alloys.

23 ntial nucleation of BCC over FCC in metallic alloys.

24 mation of <c> dislocation loops in zirconium alloys.

25 minum alloys and several 3D printed titanium alloys.

26 versatile route to synthesize nanostructured alloys.

27 ng this well-known trade-off in conventional alloys.

28 d high ductility compared to other dilute Mg alloys.

29 spectra for more than 250 metal-based binary alloys.

30 ed, including transition metals, oxides, and alloys.

31 nabling a new generation of high-performance alloys.

32 hod for assessing the ORR activity of binary alloys.

33 ntricacies of the defect processes on random alloys.

34 to that of common 6xxx series aluminum sheet alloys.

35 nical properties of medium- and high-entropy alloys.

36 heavily influenced by the degree of A' and A alloying.

37 Se using Ag doping coupled with SrSe or BaSe alloying.

38 magnetic films, liquid crystals and metallic alloys(5,6), with the notable exception of ferroelectric

39 Using a ternary alloy, a three-tiered (in structure and composition) sur

40 that Nb((1-) (x) ()) Ti(x) S(3) can be fully alloyed across the entire composition range from triclin

41 Lead-tin gradient alloying allows the formation of a graded electronic ban

42 The new ZAXME 11100 alloy also shows a rapid age-hardening response during p

43 ocrystals, well-defined multimetallic random alloy and intermetallic nanocrystals exhibit unique and

44 tion, structure, and crystal phase of random alloy and intermetallic nanocrystals has been intensivel

45 As such, random alloy and intermetallic nanocrystals have attracted exte

46 erties and widespread applications of random alloy and intermetallic nanocrystals in electrocatalysis

47 ples and strategies developed to form random alloy and intermetallic nanocrystals with enhanced perfo

48 enges for the controlled synthesis of random alloy and intermetallic nanocrystals.

49 These properties can be tailored through alloying and thermo-mechanical processing, which is ofte

50 High-entropy alloys and compounds are becoming an important class of

51 ed to a wide range of precipitation-hardened alloys and different additive manufacturing processes.

52 to bulk mechanical response of concentrated alloys and help in designing structural materials with h

53 o broadens the understanding of alkali metal alloys and hybrid-ion battery chemistry.

54 xploit this method, we must move towards new alloys and processes.

55 rcial alloys, including two wrought aluminum alloys and several 3D printed titanium alloys.

56 -x)Pt(x) (x = 0, 0.2, 0.4, 0.6, 0.8 and 1.0) alloys and the magnetostriction is greatly improved from

57 impact the structural properties of metallic alloys, and induce effects that range from strengthening

58 battery employing a sodium-potassium (Na-K) alloy anode and gallium (Ga)-based alloy cathodes is dem

59 High-capacity alloy anode materials for Li-ion batteries have long bee

60 y evolves to form optimal nanostructures for alloy anodes, as we show through electrochemical experim

61 However, practical application of porous alloying anodes is challenging because of limitations su

62 eral problems related to volume expansion of alloying anodes.

63 tes, and highlighting the deep-eutectic K-Na alloying approaches for room temperature liquid anodes.

64 Si particles in 1100 degrees C MS alloys are abnormally smaller and increased in number at

65 Metallic alloys are also well captured by this relation.

66 These alloys are amenable to crack-free 3D printing via electr

67 The low Cu content alloys are definitive examples of glasses that exhibit f

68 The locally formed tin-copper alloys are electron-conductive and meanwhile electrochem

69 Traditional metallic alloys are mixtures of elements in which the atoms of mi

70 Lightweight, recyclable, and plentiful Mg alloys are receiving increased attention due to an excep

71 Silicon germanium alloys are technologically important in microelectronics

72 between the metallic lithium and lithium tin alloy as mixed electronic and ionic conducting networks,

73 oped by combining surface-modified magnesium alloy as the internal load-bearing skeleton and bioglass

74 -directed nucleation is replicated in a bulk alloy as well as under electron irradiation, implying th

75 With in situ formed NaK liquid alloys as an anode, the dendritic growth of alkali metal

76 screening method for other binary or ternary alloys as fuel cell electrocatalysts.

77 owever, ductility or formability of metallic alloys at RT are generally inversely related to strength

78 Magnesium and its alloys attract increasingly wide attention in various fi

79 rocessing of advanced lightweight structural alloys based on magnesium and titanium rely critically o

80 ar, during calendering, porous structures in alloying-based composites easily collapse under high pre

81 n in the mechanical behaviour of engineering alloys because it ensures that flow is delocalized, enha

82 ically dispersed throughout the catalyst via alloy bonding; such catalysts combine the traditional ad

83 anching in the microstructure development of alloys by laser powder bed fusion.

84 ds in the bandgap of MoS(2), WS(2) and their alloys by transient spectroscopic study.

85 The same alloy can be tuned to form a more damage-tolerant FCC +

86 ification being negligible, transition metal alloying can significantly the improve overall catalytic

87 It is demonstrated that the synthesized alloys can be exfoliated into 2D structures, and some of

88 The discovery that noble-transition alloys can excel at hot-carrier generation reveals a new

89 Alloys can offer emergent properties and new design stra

90 Finally, future perspectives for single-atom alloy catalysts from the structural, electronic and reac

91 Most recently, single-atom alloy catalysts have been developed in which one metal i

92 Traditionally, alloy catalysts have been used instead that feature enha

93 te analysis shows that bimetallic and dilute alloy catalysts significantly enhance the selectivity to

94 alysts combine the traditional advantages of alloy catalysts with the new feature of tailoring proper

95 ructural stability relation can be broken by alloying catalytically inert strontium zirconate with th

96 um (Na-K) alloy anode and gallium (Ga)-based alloy cathodes is demonstrated.

97 entropy alloy (HEA) or complex concentrated alloy (CCA).

98 gap perovskite top cells using triple-halide alloys (chlorine, bromine, iodine) to tailor the band ga

99 tch behavior for a single-phase high entropy alloy (CoCrFeMnNi) in ultra-high vacuum and show that it

100 ly occurs via the chemical dissolution of an alloy component through a corrosion process.

101 dendrite-free sodium-potassium (Na-K) liquid alloy composed of two alkali metals is one of the ideal

102 By tuning alloy composition alone, the emission can be shifted acr

103 eport on quantitative assessment of the SnAg alloy composition.

104 In alloys, compositional complexity in the passivating oxid

105 n a Cantor-like Cr(20)Mn(6)Fe(34)Co(34)Ni(6) alloy, comprising both face-centered cubic (fcc) and hex

106 ulties in morphology control under the harsh alloying conditions.

107 Here we demonstrate a Si memristor with alloyed conduction channels that shows a stable and cont

108 led by tailoring the degradation rates of Mg alloys connected to Ti.

109 ed for AlCoCrFeNi(2.1) eutectic high entropy alloy, consisting of a lamellar arrangement of L1(2) and

110 plenishing corrosion-injected vacancies with alloy constituents, thus playing the crucial role in dec

111 ic tweezers based on a solenoid with an iron alloy core are widely used to apply large forces (~100 n

112 -NiOCoO surface layer and disordered ternary alloy core.

113 ormance of Pt-based catalyst including using alloying, core-shell structure, and high surface area op

114 ) with SWIR emission based on Hg(x)Cd(1-x)Se alloy cores red shifted to the SWIR by epitaxial deposit

115 ategy based on utilization of sacrificial Mg alloys could broaden the current palette of antibacteria

116 Transition metal dichalcogenide (TMDCs) alloys could have a wide range of physical and chemical

117 When alloyed, crystalline and optical anisotropy are largely

118 The immiscible alloy Cu-Ta has the potential for enhanced mechanical pe

119 utionarily synchronizes the reversible Fe-Mo alloying-dealloying reactions with the delithiation-lith

120 Furthermore, the alloying/dealloying of Bi occurs at different rates and

121 cant volume expansion/contraction during the alloying/dealloying processes, while the void space can

122 hedral nanoparticles was synthesized through alloying/dealloying with Bi in a tube furnace at 900-100

123 ntly discovered processing route opens a new alloy design and production path that is synergistic bet

124 Alloy design principles are described along with the str

125 esults advance a defect-aware perspective to alloy design strategies for materials capable of perform

126 g the full potential of GB segregation as an alloy design tool, and enable the design of microstructu

127 aloric effect (MCE) compared to other CoMnGe alloys doped with Si, Sn, Ti, and Ga.

128 nic devices based on eutectic gallium-indium alloy (EGaIn) using a hybrid method utilizing electron-b

129 gy change for the *NNH formation, and the 3D alloy electrocatalyst exhibits high catalytic activity f

130 rent activity between ordered and disordered alloy electrocatalysts.

131 and electrochemical modification of Mg with alloying elements (Ca, Zn), the degradation rates of Mg

132 In this work, binary Zn alloys with alloying elements Mg, Ca, Sr, Li, Mn, Fe, Cu, and Ag res

133 Yet, due to their alloying elements, such as rare-earths or aluminum, they

134 Ni alloying enables the chemisorption of nitrogen and the l

135 ped carbon nanotube array with nickel-copper alloy encapsulation on a carbon-fiber paper.

136 ecise nanomaterials via ligand tailoring and alloy engineering for a reversible stimuli-response beha

137 The undercooled liquid alloys exhibit very high fragility that increases as x d

138 ndicated that aluminium-containing magnesium alloys exhibited considerably less localised corrosion i

139 We show that the dilute alloy exhibits outstanding high strength and high ductil

140 ism at TBs that takes the responsibility for alloy failure in demanding environments.

141 The iron-chromium-aluminum alloy (FeCrAl) is an exceptional support for highly exot

142 The percentage of Ag in the AuAg alloy following AGR based on ASV is 17.8 +/- 0.6% for 4.

143 new way of synthesizing multinary supranano alloys for advanced optoelectronic applications.

144 ed to accelerate the discovery of other TMDC alloys for various applications.

145 The findings indicate that the alloys form an inner chromia-alumina solid-solution cove

146 storing lithium via a reversible tin-lithium alloy formation and enabling lithium plating underneath

147 tract elastoplastic properties of metals and alloys from instrumented indentation results using multi

148 Specifically, alloying GeTe by Sb(2) Te(3) significantly suppresses th

149 The working mechanism of the alloy "glue" is further characterized through a combinat

150 The impact of the alloy grain size and Li content, synthesis temperature,

151 The concept of multiple-principal-element alloys has recently expanded this view, as these materia

152 Galfenol (Iron-gallium) alloys have attracted significant attention as the promi

153 of hypereutectic Al-17wt.%Si and Al-20wt.%Si alloys have been investigated.

154 Chromium-iron (CrFe) binary alloys have recently been proposed to serve as the "iner

155 Gold-copper alloys have rich forms.

156 in a nanocrystalline NiFeCoCrCu high-entropy-alloy (HEA) film via ion irradiation.

157 continuous synthesis of hollow high-entropy-alloy (HEA) nanoparticles using a continuous "droplet-to

158 relatively simple Al(0.3)CoFeNi high entropy alloy (HEA) or complex concentrated alloy (CCA).

159 High entropy alloys (HEA) are an unusual class of materials where mix

160 ur core effects in single-phase high-entropy alloys (HEAs) and contributes significantly to the yield

161 High-entropy alloys (HEAs) and metallic glasses (MGs) are two materia

162 ductility in low stacking fault energy (SFE) alloys, however to achieve an unconventional increase in

163 00 nm thick thin films of Cu, Zr, and ZrCuAg alloy in a fluorine gas atmosphere provided by an in sit

164 um precipitation in an iron-nickel-aluminium alloy in situ during laser additive manufacturing(9).

165 The formation of a Pd-Zn alloy in situ was identified to be the critical factor i

166 15 at% Si alloyed in Fe substantially reduces its conductivity by

167 The catalytic activities of single-atom alloys in a few representative reactions will be further

168 and I/Br mixed-halide perovskites form solid alloys in any ratio, while only limited mixing is possib

169 decelerates intergranular corrosion of Ni-Cr alloys in molten fluoride salt at 650 degrees C.

170 y alloys in ternary systems and high-entropy alloys in quaternary or quinary systems, alluding to the

171 They are usually called medium-entropy alloys in ternary systems and high-entropy alloys in qua

172 entify the stability of 25 quasi-binary TMDC alloys, including some involving non-isovalent cations a

173 lts for indentation for different commercial alloys, including two wrought aluminum alloys and severa

174 accelerated when the degradation rate of Mg alloys increased.

175 Microstructure analysis of the MS alloys indicates that the large Si-rich microstructures

176 Now, direct transformation of bulk Mg-Li alloys into Mg alkoxide NWs is demonstrated without the

177 eld strength (270 MPa) in this new magnesium alloy is comparable to that of common 6xxx series alumin

178 The mechanical property of the Na-K alloy is confirmed by simulation and experimental charac

179 f lithium fluoride, tin, and the tin-lithium alloy is formed, which not only ensures fast lithium-ion

180 Thus, this new magnesium sheet alloy is highly attractive for sheet applications in aut

181 Here, it is demonstrated that alloying is an effective strategy to alleviate this prob

182 on in anisotropic Nb((1-) (x) ()) Ti(x) S(3) alloys is demonstrated for the first time.

183 -x) Cu (x) P(20) bulk metallic glass-forming alloys is reported where 14 < x < 27.

184 oys, yet research on metastable high-entropy alloys is still in its infancy.

185 Alloying leads to accelerated degradation, but adequate

186 This interlayer, composed of Zn, ZnLi(x) alloy, Li(3) N, Li(2) O, and other species, possesses st

187 es consisting of layers of low melting point alloy (LMPA) phase change materials fully enclosed insid

188 eries permits the direct synthesis of binary alloys (M(x)M'(3-x))(HITP)(2) (MM' = CuNi, CoNi, and CoC

189 sed liquid metal electrodes, the nontoxic Ga alloys maintain high environmental benignity.

190 rge Si-rich microstructures in Al-12.2at.%Si alloy melt are probably aggregates comprising multiple s

191 ure in engineering-lightweight Al-12.2at.%Si alloy melt at 1100 degrees C, via melt-spinning (MS) of

192 n of Si-rich microstructure in Al-12.2at.%Si alloy melt at 1100 degrees C.

193 -rich microstructures exist in Al-12.2at.%Si alloy melt, and the large Si-rich microstructures disrup

194 S) of Al(1-x)Si(x) (x = 0.03,0.07,0.122,0.2) alloy melts from different initial melt temperatures, 80

195 ation of microstructures in high temperature alloy melts is important for manufacturing of metallic c

196 of microstructures in other high temperature alloy melts.

197 Thus, our discovery of an alloyed memristor is a key step paving the way beyond vo

198 Functionalized CNT with different alloyed metal oxides enhanced the absorption efficiency

199 le) morphology and distribution in magnesium alloy Mg-5.78Zn-0.44Zr subjected to a complex multi-step

200 er multicomponent nanocrystal systems (metal alloy, mixed oxide, and chalcogenide, etc.) for diverse

201 tion phase and 2) the ultrafast synthesis of alloy MMNCs using thermal shock heating (i.e., ~1,650 K,

202 xtensive series of ultrafine and homogeneous alloy MMNCs, achieved by 1) a flexible compositional des

203 f knowledge of the ORR on extended Pt and Pt-alloy model surfaces.

204 improve the power factors but also make the alloys more prone to detrimental bipolar diffusion.

205 n strengthened (DS), multi-principal element alloys (MPEA) without the use of traditional mechanical

206 Refractory multiprincipal element alloys (MPEAs) are promising materials to meet the deman

207 ane) by surface oxygenation of platinum (Pt)-alloyed multicomponent nanoparticles (e.g., platinum-nic

208 tructure-composition-function relation of Pt-alloy nanocatalysts during ORR demands concerted efforts

209 der to understand ORR in the more complex Pt-alloy nanocatalysts.

210 three-dimensional lithium metal/lithium tin alloy nanocomposite foil realized by a simple calenderin

211 synthesis of bimetallic nickel-copper (NiCu) alloy nanoparticles confined in a sp(2) carbon framework

212 Bimodally distributed gold-copper alloy NCs and NPs are used as a model system to demonstr

213 The best ORR catalyst in the alloy NP series we studied is L1(0)-CoNiPt, which has a

214 of PtCl(4)(2-), STEM-EDS mapping shows AuPt alloy NPs with 3.9 +/- 1.3% and 41.1 +/- 8.7% Pt followi

215 tudy to explore chemical ordering upon metal alloying of M(2)AlB(2) (M from groups 3 to 9) in orthorh

216 butions of their high-index facets, internal alloying of transition metals, and surface Bi modificati

217 and analysis identified the likely phases as alloys of lead, indium, and tin.

218 ude in a series of highly crystalline binary alloys of two-dimensional electrically conducting metal-

219 This new sheet alloy offers an excellent RT formability with a high Ind

220 Second, the effect of transition metal alloying on catalytic activity differs from reaction to

221 vely) and focus on the impact of the ternary alloys on the cation vacancies and thermoelectric proper

222 A) without the use of traditional mechanical alloying or chemical reactions.

223 ion (DED) manufacturing process of a 7075-Al alloy part.

224 polymers were used to synthesize ultrasmall alloy particles.

225 Among nine Pd-Cu alloys, Pd(50)Cu(50) was identified as the most promisin

226 This strategy results in an alloyed perovskite electrocatalyst with simultaneously i

227 ks enables phase-pure, highly crystalline FA-alloyed perovskites with extraordinary optoelectronic pr

228 Alloyed perovskites with formamidinium (FA) cation have

229 l vessels, were made by carefully controlled alloying practice (primary) using very pure copper, wher

230 only had access to bronzes made by secondary alloying practice and copper with more impurities.

231 us 0.6-4.1 mum thick film, while the AZ31 Mg alloy produced a more compact 1.7-9.9 mum thick struvite

232 the near non-equilibrium microstructures of alloys produced by laser powder bed fusion (LPBF) additi

233 ts (REEs), used in electronic industries and alloy production.

234 tational studies that suggest that the Cu-Al alloys provide multiple sites and surface orientations w

235 metallic particle structure in the processed alloy provided a testbed for challenging the analytical

236 Al(0.4)Ga(0.07)In(0.53)As quaternary random alloy (RA).

237 In an optimal alloying ratio, Cu effectively regulates the Ag movement

238 lating the migration of Na ions and thus the alloying reaction kinetics.

239 ss of lithium and tin foils, and spontaneous alloying reactions.

240 ning electron microscopy observations of the alloy revealed the distinct morphology of phase precipit

241 processing parameters and thus the resulting alloy's microstructure, for example, by using high cooli

242 Single-atom alloys (SAAs) play an increasingly significant role in t

243 activation energy of (Co(x)Ni(3-x))(HITP)(2) alloys scales inversely with an increasing Ni percentage

244 Alloying selected layered transitional metal trichalcoge

245 0)Mn(20)Cr(15)Co(20)Si(5) (at%) high entropy alloy, SFE ~ 6.31 mJ m(-2).

246 ngineered CdSe/CdS@CdZnS core/crown@gradient-alloyed shell quantum wells.

247 igh temperature mechanical testing of the DS alloys showed significant improvements in strength and d

248 t the porous Mo framework derived from Fe-Mo alloy simultaneously suppresses the growth of pure Fe pa

249 responsive materials including shape memory alloys (SMAs), piezoelectrics, dielectric elastomer actu

250 nctional applications including shape memory alloys (SMAs), switches based on metal-insulator transit

251 The metastable alloy Sn(x)V(1-x)Se(2) was preferentially formed over [(

252 ap and chiroptical activity are modulated by alloying Sn with Pb, in the series of (MBA)(2)Pb(1-x)Sn(

253 ch allows us to identify candidates that are alloys, solid-solutions, or compounds with statistical v

254 se the learning framework to scan across the alloy space, and build an extensive database of segregat

255 Previous studies of steel-alloy stents described variable patency rate across indi

256 tal and theoretical results suggest that the alloying strategy generates multiple positive effects, m

257 t well characterized in random semiconductor alloys such as silicon germanium.

258 Further optimization of the ternary Zn-Li alloy system results in Zn-0.8Li-0.4Mg alloy with the ul

259 a template structure in the aluminium-copper alloy system.

260 The overarching challenge is to design alloys that are compatible with the unique additive proc

261 et to liquid, and yields liquid ternary nano-alloys that are laborious to obtain via wet-chemistry sy

262 tructures commonly occur in many engineering alloys, the analysis of stress and strain partitioning w

263 In dual-phase high-entropy alloys, the combination of local chemical environments a

264 Here, thermally evaporated Se(x) Te(1-) (x) alloy thin films with tunable bandgaps for the fabricati

265 rted to achieve unexplored quasi-binary TMDC alloys through computationally predicted stability maps.

266 melt and above the beta-transus in titanium alloy Ti-6Al-4V.

267 electrode and current collector by thermally alloying tin and copper at their interface.

268 ns at the anodes including intercalation and alloying to explore promising strategies towards low-cos

269 llic counterparts due to the presence of the alloyed transition metal atoms.

270 thermal conductivities of solid Fe and Fe-Si alloys up to 144 GPa and 3300 K.

271 gh the synthesis of a subset of 12 predicted alloys using a scalable chemical vapor transport method.

272 mic scale structural analysis on single-atom alloys using microscopy and spectroscopy tools, such as

273 and the electronic properties of single-atom alloys using X-ray spectroscopy techniques and quantum c

274 esium and two aluminium-containing magnesium alloys was characterised after 96 h at 95% RH and 22 deg

275 lk chemistry reconstructed from the FeNi(Cu) alloy, we propose that it formed by decomposition of a c

276 ements (Ca, Zn), the degradation rates of Mg alloys were controlled, and the H(2)O(2) release kinetic

277 The results showed that when the alloys were exposed to the CO(2)-containing environment,

278 mechanical integrity can be expected for Zn alloys when considering bone fracture healing.

279 l-12.2at.%Si, compared with 800 degrees C MS alloys, which demonstrates the disruption of Si-rich mic

280 rse range of intermetallics and near-surface alloys while naturally providing uncertainty quantificat

281 is the tellurium-rich WSe(2-2) (x) Te(2) (x) alloy, while the shell is the tellurium-poor WSe(2-2) (y

282 ngth 646.69 +/- 12.79 MPa and Zn-0.8Li-0.8Mn alloy with elongation 103.27 +/- 20%.

283 odegradability of surface-modified magnesium alloy with the excellent biocompatibility and osteocondu

284 Zn-Li alloy system results in Zn-0.8Li-0.4Mg alloy with the ultimate tensile strength 646.69 +/- 12.7

285 Earth's core is composed of iron (Fe) alloyed with light elements, e.g., silicon (Si).

286 tional silver (Ag) as a primary mobile metal alloyed with silicidable copper (Cu) that stabilizes swi

287 which is stabilized at ambient conditions by alloying with 10 mol % AgBiSe(2).

288 The weakened hydrogen binding of Ru by alloying with Ni and enhanced water adsorption by the pr

289 Alloying with Pb by element substitution increases the b

290 ing high-temperature magnets are Sm-Co-based alloys with a microstructure that comprises an [Formula:

291 ial across surface interfacial boundaries in alloys with a significant effect on surface reactivity,

292 In this work, binary Zn alloys with alloying elements Mg, Ca, Sr, Li, Mn, Fe, Cu

293 t this softening effect in nickel-molybdenum alloys with grain sizes below 10 nanometres(3).

294 Lightweight sheet alloys with superior mechanical performance such as high

295 By combining Mg alloys with Ti, H(2)O(2), which is an oxidizing agent th

296 he observations made for further engineering alloys with two-phase microstructures.

297 rare-earth and aluminum-free magnesium-based alloy, with trace amounts of Zn, Ca, and Mn (~ 2% by wt.

298 Eutectic high entropy alloys, with lamellar arrangement of solid solution phas

299 ave been the basis of the design of numerous alloys, yet research on metastable high-entropy alloys i

300 Here we design a new magnesium sheet alloy-ZAXME11100 (Mg-1.0Zn-1.0Al-0.5Ca-0.4Mn-0.2Ce, wt.