ライフサイエンスコーパス: metallic

1 ed nanostructures can be considered as quasi-metallic.

2 atomically engineer metal doping sites onto metallic 1T-MoS(2), using Anderson-type polyoxometalates

3 ides and oxides, Xenes, Mxenes and other non-metallic 2D materials.

4 is study extend the current understanding of metallic 2D-TMDs in the search for exotic low-dimensiona

5 pplied to a biphasic structure, comprising a metallic adhesion layer coated with EGaIn, to create sof

6 s a core-shell structure comprised of an all-metallic Ag(53) kernel surrounded by an Ag(25) discontin

7 Metallic alloys are also well captured by this relation.

8 Traditional metallic alloys are mixtures of elements in which the at

9 However, ductility or formability of metallic alloys at RT are generally inversely related to

10 ltrathin magnetic films, liquid crystals and metallic alloys(5,6), with the notable exception of ferr

11 ofoundly impact the structural properties of metallic alloys, and induce effects that range from stre

12 e preferential nucleation of BCC over FCC in metallic alloys.

13 s as are crystallographic microstructures in metallic alloys.

14 Eleven brands and five types of packaging (metallic aluminium bag, carton, high-density polyethylen

15 Metallic aluminium bags were the least migrating packagi

16 mission spectroscopy measurements reveal the metallic and electronic structure of the as-grown sample

17 In manganites, the balance between metallic and insulating phases can be tuned by the latti

18 ctral features, connected to semiconducting, metallic and magnetic properties of solids, as well as u

19 Using this approach, metallic and metallic oxide particles with different rad

20 antiferromagnetic ground states, LNO remains metallic and non-magnetic down to the lowest temperature

21 ilar Poisson's ratio to that of many ductile metallic and organic glasses.

22 These membranes are typically metallic and organic materials with good ductility that

23 e intercalation and solid state reduction of metallic and semiconducting enriched HiPco SWCNTs.

24 ctron systems, including models of realistic metallic and semiconducting solids.

25 The metastable metallic and small band gap phases of group VI TMDs disp

26 inantly two different chemistries, including metallic and titanium dioxide (TiO(2)).

27 Two phenotypes, the "metallic" and "rufipennis" are the most widely distribut

28 ade using an array of three-dimensional (3D) metallic annular cracks on polymeric microstructures pos

29 ated compound of HSrRuO(3) with paramagnetic metallic as ground state.

30 t via increasing the intrinsic reactivity of metallic atoms and enhancing the synergistic effect betw

31 Previously reported metallic B(50)C(2) structures with carbons inserted only

32 Our results reveal that the metallic bandwidth in GNRs can be tuned over a wide rang

33 arrier mobility of single crystals exhibit a metallic behavior with a typical T(-1.5) dependence, ind

34 in the conduction level and thus to a highly metallic behavior.

35 is still observed despite the TBG exhibiting metallic behaviour across the whole range of electron de

36 how a transition from semiconducting-like to metallic behaviour with decreasing temperature.

37 Fermi surface volume-a key driver of strange-metallic behaviour.

38 GBs with controlled misorientation can endow metallic bicrystals with endurable cyclic deformability

39 ng physicochemical conditions; the resulting metallic biological complement is termed the metallome.

40 nitride has a superlattice of insulating and metallic blocks.

41 Here, we find that the metallic blue appearance of the fruits is produced by gl

42 It produces ripe metallic blue fruits throughout winter [1].

43 nanomaterials due to the strong interatomic metallic bonding.

44 The dodecaborides were confirmed to be metallic by band structure calculations, diffuse reflect

45 Metallic catalysts with nanopores are advantageous on im

46 t (i) mimosine has high binding affinity for metallic cations at alkaline pH, Fe(III)-mimosine comple

47 Herein, recent advancements in subwavelength metallic cavities that can improve performance, even wit

48 ctor quantum wells to the photonic mode of a metallic cavity in order to custom-tailor the population

49 The bio-inspired metallic cellular structure (with an internal grid of la

50 tes and CB[8] form 2:1 assemblies, with both metallic centers sitting on top of one another at one of

51 llapses and the Drude-like peak with strange metallic character appears.

52 These binary systems exhibit a clear metallic character.

53 (191)(SPh-tBu)(66) having both molecular and metallic characteristics, explored crystallographically

54 andomly assigned to presurgical marking with metallic clips (Group A) or with 125I seeds (Group B).

55 cantly smaller surgical specimens than using metallic clips.

56 and agglomeration of single metal sites into metallic clusters.

57 Through these catheters, numerous metallic coils are often pushed into the bleeding artery

58 es, which can be promoted through the use of metallic complexes.

59 ditional robots are mostly built from rigid, metallic components and electromagnetic motors, which ma

60 lloy melts is important for manufacturing of metallic components but extremely challenging.

61 gh-entropy ceramics, containing four or more metallic components distributed homogeneously in the met

62 system to demonstrate the semiconductive-to-metallic conductivity transition, quantized capacitive c

63 ther fields due to their high surface areas, metallic conductivity, biocompatibility, and attractive

64 ductive films due to their high strength and metallic conductivity.

65 onventional uniform flow profile imaged in a metallic conductor and also in a low-mobility graphene c

66 iable technology is the deposition of a top, metallic contact over the self-assembled monolayer (SAM)

67 xperiments revealed that copper(I) oxide and metallic copper were the active phases in virus removal

68 ysis reveals that 1 features a multi-shelled metallic core of Ag(6) @Ag(24) @Ag(60) @Ag(12) .

69 that lighter Si has partitioned into Earth's metallic core, our results indicate that the super-chond

70 the surface oxide layer is fully reduced to metallic Cu before the onset potential for CO(2)RR, and

71 ing-linker defects maximizes the fraction of metallic Cu interfaced to ZrO(2) nodes leading to a mate

72 rption and conversion, while the presence of metallic Cu is also necessary to facilitate H(2) dissoci

73 duced 1-2 nm amorphous ZrO(2) supported over metallic Cu particles.

74 iation enables the gradual separation of the metallic Cu phase from the Cu-Sn ICL, which provides a r

75 However, at high pressures metallic curium undergoes a transition from localized to

76 cter that lies closer in its behavior to the metallic density wave seen in chromium metal than the in

77 -guided cardiovascular catheterizations with metallic devices, diagnostic imaging in high-susceptibil

78 The metallic edge states are revealed by scanning probe micr

79 on of isoimpratorin in the synthesis of nano-metallic electro and photocatalysts, especially silver n

80 eratures above 240 degrees C to maintain the metallic electrodes in a molten state.

81 ctronic structure and to the coupling to the metallic electrodes.

82 nic states, one involving excitations of the metallic electrons, namely, the HE states, and the other

83 plasmon peak, characteristic of delocalized metallic electrons.

84 thium, the lightest and most electronegative metallic element, has long been considered the ultimate

85 Arsenic is a pro-oxidant metallic element.

86 The results show that multiple metallic elements, namely Pb and Zn, can be independentl

87 olutions of generally equiatomic mixtures of metallic elements.

88 ave been enhanced by the catalytic effect of metallic Fe-Ni-C liquid coexisting with graphite during

89 is transition is stable in the presence of a metallic Fermi sea, and its universality class in the lo

90 La(0.7)Sr(0.3)MnO(3), a strong semi-metallic ferromagnet having robust spin polarization and

91 DMI manifests at metallic ferromagnet/heavy-metal interfaces, owing to in

92 shed that intense photoexcitation in several metallic ferromagnets leads to a drop in magnetization o

93 than those required for switching nonlayered metallic ferromagnets such as CoFeB.

94 nerant electron magnetism similar to that in metallic ferromagnets.

95 is far below the critical thickness of most metallic films.

96 For an experimental demonstration, the metallic filter was made with either a stainless steel o

97 rms have been proposed, including the use of metallic filters(8,9), multilayer mirrors(10) and manipu

98 Intraorbital metallic foreign bodies have varied clinical presentatio

99 ss a bimodal distribution among silicate and metallic fractions of EC because of its formation under

100 ly-thin gate dielectrics and atomically-flat metallic gates, we measure the electron-electron scatter

101 the way for atomic-scale in situ studies of metallic GB phase transformations, which were previously

102 metasurfaces typically consist of an ordered metallic geometry that is patterned onto a dielectric su

103 on the coating of diamond dicing blades with metallic glass (MG) coating to reduce chipping when used

104 and scalable approach for the fabrication of metallic glass fibres with nanoscale architectures based

105 A high-throughput investigation of metallic glass formation via solid-state reaction was re

106 sma sintered Fe(48)Cr(15)Mo(14)Y(2)C(15)B(6) metallic glass is established by analyzing the crystal s

107 first direct quantification of oxidation in metallic glass powder by ultra-small angle X-ray scatter

108 oxidation of Fe(48)Cr(15)Mo(14)Y(2)C(15)B(6) metallic glass powder in the supercooled region are inve

109 Studies on other metallic glass samples with different compositions also

110 ion in this spark plasma sintered iron based metallic glass was established to be from pre-existing n

111 ttractive performance characteristics of the metallic glass while alleviating its negative undesirabl

112 structural ordering in a Ce(65)Al(10)Co(25) metallic glass, and a reverse disordering process via a

113 We demonstrate in particular an implantable metallic glass-based fibre probe tested in vivo for a st

114 of near-eutectic Pt(80-x) Cu (x) P(20) bulk metallic glass-forming alloys is reported where 14 < x <

115 report the design of iridium/nickel/tantalum metallic glasses (and others also containing boron) with

116 When metallic glasses (MGs) are subjected to mechanical loads

117 High-entropy alloys (HEAs) and metallic glasses (MGs) are two material classes based on

118 Metallic glasses (MGs) lack the crystallinity of convent

119 Metallic glasses are expected to have quite tunable stru

120 Zr-based metallic glasses are prepared by quenching supercooled l

121 Bulk metallic glasses can exhibit strength and elasticity sur

122 Understanding the thermal stability of metallic glasses is critical to determining their safe t

123 ver, effectively modulating the structure of metallic glasses is rather difficult.

124 Micro- and nanoscale metallic glasses offer exciting opportunities for both f

125 "Designing" metallic glasses to exhibit properties beyond those offe

126 and pressure, extending accessible states of metallic glasses to unexplored configuration spaces.

127 Our method yields well-ordered and uniform metallic glasses with controllable feature sizes down to

128 Bulk metallic glasses with glass transition temperatures grea

129 vin that is wider than that of most existing metallic glasses(12).

130 the fabrication and utilization of nanoscale metallic glasses, however, remain unresolved.

131 Whether a metallic ground state exists in a two-dimensional system

132 In this process, metallic heterodimer NPs were used as catalysts for NW g

133 ontrolled by the chemical composition of the metallic heterodimer used.

134 duced switching in a polycrystalline PtMn/Pt metallic heterostructure.

135 at the initial HgCl(2) was partly reduced to metallic Hg(0) and that Hg forms of different mobility a

136 d as an alternative way to attain the atomic metallic hydrogen state or high-temperature superconduct

137 Forces on metallic implants and radiofrequency power deposition an

138 terahertz metamaterial containing 3D-chiral metallic inclusions and achiral vanadium dioxide inclusi

139 rs such as polymeric nanoparticles/micelles, metallic/inorganic NPs, and lipid-based NPs (Liposome, s

140 c gates, van der Waals heterostructures, and metallic interfaces between insulating oxides.

141 the variation in the neutral metal atoms and metallic ions above thunderstorms.

142 tter," "umami," and "sour." TBCs that detect metallic ions, described by humans as "salty," are undef

143 We report the wide-spread occurrence of metallic iron whiskers as a decomposition product formed

144 onds, nanographite, and nanometric grains of metallic iron, cohenite, troilite, and likely schreibers

145 wing that SAMHD1 utilises an active site, bi-metallic iron-magnesium centre that positions a hydroxid

146 rbit coupling in the spin dynamics in a half-metallic La(0.7) Sr(0.3) MnO(3) film by ultrafast pump-p

147 We find that the intensification of metallic layered phenomena above thunderstorms is associ

148 s a smooth transition between insulating and metallic layers in giant gas planets, and reconciles exi

149 nce magnetic layer separated by non-magnetic metallic layers.

150 lic surface, restricts the leakage of liquid metallic Li and enables good thermal tolerance of the Li

151 The differences between metallic Li and Na are summarized according to advanced

152 ten-salt Li metal batteries using a pristine metallic Li anode.

153 this novel electrolyte enabled rechargeable metallic Li battery with high energy (178 Wh kg(-1) ) an

154 Plating of metallic Li on graphite anodes is a critical reason for

155 However, integrating metallic Li with solid-electrolytes using scalable proce

156 D Li(5) B(4) fibrillar framework filled with metallic Li, which maintains its initial structure at 32

157 bon paint which is highly conductive and has metallic-like behavior.

158 m insulating(5-8) or semiconducting(9,10) to metallic-like behaviour(11).

159 evel spanning from the semiconducting to the metallic limit.

160 The strong affinity between the metallic lithium and lithium tin alloy as mixed electron

161 Herein, the Li dendrite growth of metallic lithium anode is suppressed by forming a lithiu

162 yte, as well as from intercalated and plated metallic lithium in a multilayer (rolled) commercial pou

163 Li-containing cathode, circumventing use of metallic lithium in constructing next-generation batteri

164 Metallic lithium is a promising anode to increase the en

165 Metallic lithium is the most competitive anode material

166 hium (that is, there is a direct tie-line to metallic lithium on the equilibrium phase diagram), so t

167 investigated the deposition and stripping of metallic lithium or sodium held within a large number of

168 lized reagents due to the high reactivity of metallic lithium.

169 ydrophobic solid-electrolyte interphase on a metallic-lithium anode that allows for handling of the t

170 Twisted bilayer graphene (tBLG) is a metallic material with two degenerate van Hove singulari

171 ect is a phenomenon by which plastic slip in metallic materials becomes unstable, resulting in jerky

172 Additively manufactured (AM) metallic materials commonly possess substantial microsca

173 Metallic materials have enabled technological progress o

174 The vast compositional space of metallic materials provides ample opportunity to design

175 ion of the production of high economic value metallic materials, enabling innovative, geometrically c

176 stringent requirement on electrodes based on metallic materials.

177 (DCB) has been investigated, as it leaves no metallic mesh.

178 he proposed framework is leveraged to design metallic metamolecules for arbitrary manipulation of the

179 lets sinter during DEP to form a stretchable metallic microwire that retains its shape after curing t

180 th micron-scale ceramic "bricks" bonded by a metallic "mortar" are projected to result in higher stre

181 ealize controllable plastic reversibility in metallic nanocrystals.

182 dvances in promoting cyclic deformability of metallic nanomaterials.

183 Metallic nanoparticle solutions are routinely characteri

184 to investigate possible cytotoxic effects of metallic nanoparticles (NPs).

185 particles, and a wide range of inorganic and metallic nanoparticles are covered in detail.

186 This study demonstrates that certain metallic nanoparticles can be used in combination to imp

187 omposites consisting of a polymer matrix and metallic nanoparticles can merge the functional, structu

188 In this work, we report the observation of metallic nanoparticles formation and stabilization on ca

189 Functionalized metallic nanoparticles have been used as probes for prot

190 We find that the formation of metallic nanoparticles is associated with the simultaneo

191 large aggregated metal oxide particles into metallic nanoparticles just ~10 nm in size, uniformly di

192 trongly concentrated in the gaps between the metallic nanoparticles, and the simultaneous focusing an

193 ept allowing extensive, controlled growth of metallic nanoparticles, at nanoscale proximity, within a

194 Carbon nanoparticles, metallic nanoparticles, metal oxide nanoparticles, and v

195 gesting that this mechanism is universal for metallic nanopores.

196 yst to investigate the catalytic behavior of metallic nanopores.

197 A low-cost metallic nanostructure-based surface plasmon resonance (

198 Surface plasmon resonances of metallic nanostructures offer great opportunities to gui

199 LSPR imaging with dark-field microscopy on metallic nanostructures suffers from low light throughpu

200 -scale optical confinement achieved by these metallic nanostructures vastly increase spectroscopic se

201 one-dimensional conductive materials such as metallic nanowires and carbon nanotubes in an elastomer

202 culations, validate the phase purity and the metallic nature.

203 , we grow an epitaxial-HBAR, consisting of a metallic NbN bottom electrode and a piezoelectric GaN fi

204 ystal overlayer, and form an oriented porous metallic network (OPEN) structure in which the 2DC can s

205 ased MOFs and subsequently transformed to 3D metallic networks via a chemical reduction process.

206 absorption spectroscopy, where a reversible metallic Ni species (Ni(0)) is observed in alkaline cond

207 The insulation between the metallic NiTi structure and the Pt electrode layer is re

208 p sea mining concerns the extraction of poly-metallic nodules, cobalt-rich crusts and sulphide deposi

209 cten-3-one, which imparted slight sulfur and metallic notes, although they disappeared during storage

210 idate nanospecific effects on dissolution of metallic NPs in freshwater and similar media.

211 ich the valley-polarized channels are either metallic or develop a spectroscopic gap.

212 chemical properties compared to traditional metallic, organic, and oxide glasses.

213 Using this approach, metallic and metallic oxide particles with different radii were disti

214 Metallic oxides are used at 5%, 10%, and 20% concentrati

215 he CNT nanoparticles are functionalized with metallic oxides such as Cobalt oxide, Iron oxide, and Co

216 Welding fumes (WFs) are a complex mix of metallic oxides, fluorides and silicates that can cause

217 growth to form semiconductor NWs capped with metallic particles (Au, Ag, Co, Ni).

218 ctive redox work is also material dependent: metallic particles grow to a larger extent over charged

219 oolant water was collected and the number of metallic particles were counted under a light microscope

220 Here we report the discovery of metallic particles, dominantly of FeNi (Fe(0.71)Ni(0.24)

221 ve metal species that produces the ex-solved metallic particles.

222 o investigates the controlled formation of a metallic phase (Li(7) Ti(5) O(12) ) percolating through

223 They suggest that charge fluctuation in the metallic phase of intrinsic VO(2) results in the formati

224 reveal that this heterostructure possesses a metallic phase with high conductivity and ferromagnetic

225 is known, but it is restricted to condensed metallic phases(8), the hexagonal pores of coordination

226 edictions such as Dirac half-metallicity and metallic phases, indicating that the intra-atomic intera

227 ndidate superconductor to Mott insulator and metallic phases.

228 e-sensor array is coated with an ensemble of metallic plasmonic nanostructures that only transmits li

229 hed is reported, which matches the EMI SE of metallic plates over an exceptionally broad frequency ra

230 The demonstration that increasingly metallic pnictogens form halogen bonds sufficiently stro

231 rtight containers such as glass jars, cans o metallic pouches with cover brine or N(2) atmosphere.

232 g of a high powered laser over a thin bed of metallic powder to create a single layer, which may then

233 ion of complex, three-dimensional parts from metallic powder using a computer-aided design model(1-3)

234 ion of mechanically-activated nanostructured metallic precursors in nitrogen and consolidated by spar

235 ydiazenediyl chains, these compounds exhibit metallic properties.

236 s an alternative to pre-formed carbanions or metallic reductants in C=X addition.

237 euteration reactions that use stoichiometric metallic reductants.

238 Upon entering the metallic regime, the Mott gap collapses and the Drude-li

239 of the compounds deep in the insulating and metallic regimes are almost symmetric, those of the semi

240 lane electric fields, unscreened even in the metallic regions, which profoundly alter the quantum Hal

241 d sample were placed in a specially designed metallic rotor that prevents the heating of absorbing so

242 nosis of the bioabsorbable sirolimus-eluting metallic scaffold (Magmaris) remain unknown.

243 paration distance between the graphene and a metallic screening layer(12,13).

244 a-liquid, and surface-supported synthesis of metallic, semiconducting, metal oxide, and carbon-based

245 Here, we show that metallic-semiconducting junctions in aptasensors are sen

246 nalization of iron oxide nanoworms (NWs) and metallic silver nanoparticles (AgNPs) with PL3 peptide i

247 derstanding and visualising mosaicity within metallic single crystals and provides the foundation for

248 ts with different surface atom densities, bi-metallic sites, and metal aggregation states are achieve

249 (23) Na T(2) -contrast MRI of metallic sodium offers a clear, routine method for obser

250 bserve, for the first time, the formation of metallic sodium species on hard carbon upon first charge

251 ute blue electrolytes to concentrated bronze metallic solutions.

252 s in general, and the presence of coexisting metallic species for an accurate description of the degr

253 The integration of two different metallic species, Pd and Au, into a surface structure on

254 he approach is evaluated experimentally with metallic spheres of known diameters ranging from 0.79 to

255 uprate high-temperature superconductors, the metallic state above the highest transition temperature

256 for CO(2)RR, and the catalyst maintains the metallic state across the potentials relevant to the CO(

257 ansition, classifying the metamaterials into metallic state and dielectric state.

258 or heterostructure, in which a field-induced metallic state at the interface accelerates proton trans

259 Our measurements suggest that the anomalous metallic state is bosonic and that the saturation of pha

260 ional reference structures confirm the quasi-metallic state of the polymer, show high rectification r

261 rafast photo-doping drives the system into a metallic state on a timescale of ~150 fs without yet per

262 ring the buildup of a three-dimensional (3D) metallic state that follows charge photodoping.

263 The topological phase transition from the metallic state to the dielectric state occurs when the f

264 that has not been previously observed in the metallic state.

265 The design and fabrication of robust metallic states in graphene nanoribbons (GNRs) are chall

266 Furthermore, the metallic states of the nanoparticles are renewed during

267 ween topological and normal insulators hosts metallic states that appear due to the change in band to

268 (010) surface, we find a rich assemblage of metallic states with two-dimensional dispersion.

269 patient data from 19 prospective, randomized metallic stent trials maintained at a leading academic r

270 n and forming a molecular bridge between the metallic STM tip electrode and the metallic surface elec

271 ferroelectric lead titanate (PbTiO(3)) on a metallic strontium ruthenate (SrRuO(3)) buffer using a c

272 V) enables new approaches for production of metallic structures at room temperature, on-demand fluid

273 Fabrication of bio-templated metallic structures is limited by differences in propert

274 Such asymmetric metallic structures lead to distinct wetting and optical

275 components distributed homogeneously in the metallic sublattice.

276 l surface-assisted chemical reactions, where metallic substrates strongly screen their designer elect

277 A binary metallic superoscillatory lens assisted with annular sub

278 tween the metallic STM tip electrode and the metallic surface electrode.

279 nge and the contact loss, as well as a dense metallic surface phase, deteriorate the electrochemical

280 h the antigen is enabled by its binding to a metallic surface that serves as a source for electrons.

281 ism driven by a random reconstruction of the metallic surface, an effect that dominates over any plas

282 e creation of stable molecular monolayers on metallic surfaces is a fundamental challenge of surface

283 maging of Pseudomonas aeruginosa biofilms on metallic surfaces using an infrared camera.

284 cles leads to the formation of step sites on metallic surfaces.

285 length via multiple reflections by patterned metallic surfaces.

286 uiding the experimental exploration of multi-metallic systems that go beyond the limitations of conve

287 While in metallic systems, spin-orbit coupling arises from a prox

288 ed multilayered films composed of disordered metallic Ta and magnetic FeNi nanoisland layers, where f

289 pic in-plane structures featuring stripes of metallic TaTe(2) and semiconducting FeTe(2), alpha-TaFeT

290 The metallic tin (Sn) anode is a promising candidate for nex

291 We detect the presence of metallic tin among the degradation products, which we su

292 Here, by encapsulating nanoparticles of metallic tin in mechanically robust graphene tubes, we s

293 lculations reveal that plasmons of monolayer metallic transition metal dichalcogenides are tunable, l

294 tegy for two-dimensional vdWH arrays between metallic transition-metal dichalcogenides (m-TMDs) and s

295 A quasi-metallic transport behavior is observed at room temperat

296 Here we demonstrate strange metallic transport in the doped two-dimensional Hubbard

297 hese findings highlight the critical role of metallic tubes in CNT-FET biosensor devices and demonstr

298 d on the top layer of the GaAs substrate and metallic via-holes implemented in the central patch of e

299 s and demonstrate that the Cccm phase is non-metallic, with molecular H(2) units in the crystal struc

300 is known to promote the direct insertion of metallic zinc powder into organohalides in the practical