ライフサイエンスコーパス: noble

1 ays (0.39) and wichmannii (0.32) compared to nobles (0.09) and medicinal cultivars (0.10).

2 bimetallic alloy nanoparticles comprising a noble and a nonnoble metal is expected to cause the form

3 Ten permutations of noble and base metals (platinum, palladium, copper, nick

4 oxidation and reduction catalysts, involving noble and non-noble metal ions, we limit our discussion

5 ntum efficiency of 1.4% was recorded for the noble- and toxic-metal free photocatalytic system.

6 amental understanding of the behavior of non-noble based materials toward the hydrogen evolution reac

7 NOBLE Coder implements a general algorithm for matching

8 Advantages of NOBLE Coder include its interactive terminology builder

9 NOBLE Coder is comparable to other widely used concept r

10 We describe key advantages of the NOBLE Coder system and associated tools, including its g

11 flow cell, the activity and stability of non-noble electrocatalysts is presented.

12 energy recovery data were collected from 200 Noble Energy Inc. wells to estimate the consumptive wate

13 cessibility could be proved by accommodating noble gas atoms into the pocket in the crystalline state

14 gs enable the study of individually confined noble gas atoms using surface science methods, opening u

15 ar HgF4 was synthesized in a low-temperature noble gas but the potential of Hg to form compounds beyo

16 have investigated nanoplasma formation from noble gas clusters exposed to high-intensity hard-x-ray

17 e first time the expected carbon isotope and noble gas compositions of captured CO2 streams from a ra

18 isotope compositions with gas chemistry and noble gas compositions of forearc and arc front springs

19 ane concentrations; isotopes of methane; and noble gas concentrations from 88 wells in Pennsylvania w

20 This is consistent with predicted noble gas concentrations in a water phase in contact wit

21 pe fractionation is possible during capture; noble gas concentrations will be controlled by the captu

22 Noble gas data appear to rule out gas contamination by u

23 increase is consistent with inferences from noble gas data.

24 bility of proteins and can be mapped through noble gas diffusion and docking.

25 model, length of ischemia, conditioning and noble gas dose, duration of administration of the gas, e

26 The flux of atmospheric noble gas entering the deep Earth through subduction and

27 arison of the results to those obtained from noble gas experiments and trajectory simulations, the sp

28 cent containers, effectively imprisoning the noble gas in the solid state.

29 Noble gas isotope and hydrocarbon data link four contami

30 streams derived from fossil fuels will have noble gas isotope ratios reflecting a radiogenic compone

31 deep saline groundwater, (ii) characteristic noble gas isotopes, and (iii) spatial relationships betw

32 r of continuous, high-precision and accuracy noble gas measurements at substantially reduced cost and

33 neuroprotection, using crystallography under noble gas pressure, mostly at room temperature.

34 However, noble gas proxy isotopes produced during neutron irradia

35 is required to explain the light atmospheric noble gas signature of Barnett Shale production gas.

36 These distinct Strawn and Barnett noble gas signatures are likely the reflection of distin

37 While noble gas signatures of Strawn and stray gas are consist

38 e similarity of Strawn and stray gas crustal noble gas signatures suggests that the Strawn is the sou

39 wn gas have distinct crustal and atmospheric noble gas signatures, allowing clear identification of t

40 use of hyperpolarized nuclei, such as in the noble gas xenon, but previous reporters acting on such n

41 Information on noble gas, organ, species, model, length of ischemia, co

42 e rich and still enigmatic chemistry of this noble gas.

43 rare example in which HF is coordinated to a noble gas.

44 to the weak van der Waals interaction, rare (noble)-gas solids are a near-ideal medium in which to st

45 gas oxocation as well as a rare example of a noble-gas dication.

46 known examples of cage anions that contain a noble-gas element.

47 2OOSO2CH3 and subsequently isolated in solid noble-gas matrices.

48 ested here: combining stream hydrocarbon and noble-gas measurements with reach mass-balance modeling

49 ecedented example of a xenon(II) oxide and a noble-gas oxocation as well as a rare example of a noble

50 f isolable compounds which contain different noble-gas-element bonds is limited for xenon and even mo

51 lly show strong depletion of all atmospheric noble gases ((20)Ne, (36)Ar, (84)Kr, (132)Xe) with respe

52 on [B12 Cl11 ](-) spontaneously binds to the noble gases (Ngs) xenon and krypton at room temperature

53 l (4)He, (21)Ne, and (40)Ar and suggest that noble gases and methane originate from common sedimentar

54 roversial nature of chemical bonding between noble gases and noble metals is addressed.

55 owledge, the first comprehensive analyses of noble gases and their isotopes (e.g., (4)He, (20)Ne, (36

56 In this study, we report that noble gases are hosted by two major sites within the int

57 that sorb, capture and/or store the heavier noble gases are of interest because of their potential f

58 The noble gases are the most inert group of the periodic tab

59 However, the extent to which atmospheric noble gases are trapped in minerals crystallized during

60 Noble gases dissolved in natural waters are useful trace

61 a subduction barrier for atmospheric-derived noble gases does not exist at mantle depths associated w

62 is study presents the complete set of stable noble gases for Barnett Shale and Strawn Group productio

63 Noble gases have been attributed to organ protective eff

64 We determined radiogenic and cosmogenic noble gases in a mudstone on the floor of Gale Crater.

65 Noble gases in amine-captured CO2 streams are likely to

66 sting technology to remove these radioactive noble gases is a costly cryogenic distillation; alternat

67 The cryogenic separation of noble gases is energy-intensive and expensive, especiall

68 of studies show a protective effect of these noble gases on ischemia reperfusion injury across a broa

69 The confinement of noble gases on nanostructured surfaces, in contrast to b

70 re are no prior examples of perovskites with noble gases on the A-sites.

71 (conventional (1)H as well as hyperpolarized noble gases such as (129)Xe, (3)He, and inhaled O2 and (

72 study the chemical nature of the bonding of noble gases to closed-shell systems containing gold.

73 itic refractory organics and the trapping of noble gases took place simultaneously in the ionized are

74 tural features with chondritic organics, and noble gases trapped during the experiments reproduce the

75 realized until the abundances of atmospheric noble gases trapped in exhumed UHP rocks are known.

76 Here we present high precision analyses of noble gases trapped in fluid inclusions of Archean quart

77 th the isotopic composition of nonradiogenic noble gases trapped in minerals formed during subsolidus

78 nce of the time at which the neuroprotective noble gases xenon and argon should be administered, duri

79 plasma setup from gas mixtures (H2(O)-CO-N2-noble gases) reminiscent of the protosolar nebula compos

80 The Group 18 elements (noble gases) were the last ones in the periodic system t

81 g, and comparative efficacy of the different noble gases, as well as confirmation in large animal mod

82 to fcc-to-hcp transformations in Al and the noble gases, the transformation is sluggish, occurring o

83 By considering mixtures of noble gases, we show that, depending on the phase behavi

84 ett Shale footprint in Texas using dissolved noble gases, with particular emphasis on (84)Kr and (132

85 usly assess forearc recycling of atmospheric noble gases.

86 t they contain metal and are repositories of noble gases.

87 Several noble gasses have been shown to elicit biological respon

88 As the ferromagnet Fe becomes more noble in the FePt compound, the electronic structure is

89 sses chemical characteristics reminiscent of noble, late-metals.

90 The non-noble materials are stable at HER potentials but dissolv

91 AgNPs are biocompatible stable noble materials especially in biological sensing.

92 ples originating from four cultivars groups (noble, medicinal, two-days and wichmannii), were analyse

93 ts offer scalability, but only if they match noble metal activities.

94 ional group tolerance without the use of any noble metal additives.

95 al catalytic bottom-up growth paradigm using noble metal and metal alloy catalysts.

96 of such electronic interactions between the noble metal and oxide can be exploited for engineering r

97 However, effects of the distance between the noble metal and oxophilic metal active sites on the cata

98 th their mass activity reaching 0.20 A/mg of noble metal at -0.1 V vs Ag/AgCl (4 M KCl); this was ove

99 ong OER catalysts in acidic solution, no non-noble metal based materials showed promising activity an

100 hes include the partial hydrogenation over a noble metal catalyst and the solvent extraction of crack

101 Only noble metal catalysts based on iridium and ruthenium hav

102 EGC1-10-2 provide a promising alternative to noble metal catalysts by using abundant natural biologic

103 are able to design a low-cost alternative to noble metal catalysts for efficient electrocatalytic pro

104 n overview of recent developments in the non-noble metal catalysts for electrochemical hydrogen evolu

105 ndant alternatives to photocathodes based on noble metal catalysts for solar-driven hydrogen producti

106 emperature, organometallic C-H activation by noble metal catalysts that produce alkenes and hydrogen

107 ns with a combination of oxophilic metal and noble metal catalysts to yield branched C7 -C10 hydrocar

108 Replacing rare and expensive noble metal catalysts with inexpensive and earth-abundan

109 l oxides and chalcogenides, carbon-based non-noble metal catalysts, and metal-free catalysts.

110 t and less expensive catalysts compared with noble metal catalysts, especially for the oxygen evoluti

111 The high cost and scarcity of noble metal catalysts, such as Pt, have hindered the hyd

112 as a promising cost-effective substitute for noble metal catalysts.

113 ecial focus is put on recent progress in non-noble metal catalysts.

114 the activity, and increase the stability of noble metal catalysts.

115 much higher than that afforded by other non-noble metal cathode materials and distinguishes Bi-CMEC

116 ween atomically precise, monolayer protected noble metal clusters using Au25(SR)18 and Ag44(SR)30 (RS

117 al In2S3-CdIn2S4 nanotubes without employing noble metal cocatalysts in the catalytic system manifest

118 Whereas noble metal compounds have long been central in catalysi

119 ad among the highest HER activity of any non-noble metal electrocatalyst reported to date, producing

120 by the high cost associated with the use of noble metal electrodes, the need of high-voltage electri

121 e low-temperature oxygen electrocatalysis on noble metal films, leading to significant enhancements i

122 transition metal other than from Group VI, a noble metal in this case.

123 reduction catalysts, involving noble and non-noble metal ions, we limit our discussion to the cases i

124 n as fuels from water sustainably to replace noble metal materials.

125 Atomically precise thiolate-protected noble metal molecular nanoparticles are a promising clas

126 de nanoparticles coated with atomically thin noble metal monolayers by carburizing mixtures of noble

127 property that has yet to be explored for the noble metal nanoclusters (NCs).

128 reactions, but applicable to all methods of noble metal nanocrystal synthesis.

129 Platonic noble metal nanocrystals (NCs) have attracted considerat

130 Assembly of noble metal nanocrystals into free-standing two-dimensio

131 ormic acid, methanol and carbon monoxide) of noble metal nanomaterials are also briefly introduced.

132 The functional properties of noble metal nanomaterials are determined by their size,

133 n recent years, the crystal phase control of noble metal nanomaterials has emerged as an efficient an

134 of the crystal phase-controlled synthesis of noble metal nanomaterials, we will provide some perspect

135 in the crystal phase-controlled synthesis of noble metal nanomaterials.

136 ystal phase-controlled synthesis of advanced noble metal nanomaterials.

137 expression levels, we demonstrate here that noble metal nanoparticle (NP) immunolabeling in combinat

138 netic near-field coupling between individual noble metal nanoparticle labels to resolve subdiffractio

139 ative seed refinement leads to unprecedented noble metal nanoparticle uniformities and purities for e

140 urface plasmon resonance (LSPR) occurring in noble metal nanoparticles (e.g., Au) is a widely used ph

141 The noble metal nanoparticles (NPs) exhibit high electrocata

142 Nanostructures decorated with noble metal nanoparticles (NPs) exhibit potential for us

143 the electrospray plume on a surface yielded noble metal nanoparticles (NPs) under ambient conditions

144 of surfactant-assisted synthesized colloidal noble metal nanoparticles (NPs, such as Au NPs) on solid

145 te that metal oxide materials decorated with noble metal nanoparticles advance visible light photocat

146 Non-noble metal nanoparticles are notoriously difficult to p

147 Bimetallic hollow, porous noble metal nanoparticles are of broad interest for biom

148 e to their advantageous material properties, noble metal nanoparticles are versatile tools in biosens

149 ynthesizing optical metamaterials based upon noble metal nanoparticles by enabling the crystallizatio

150 neous monitoring of complex environments and noble metal nanoparticles in real time.

151 Much of the interest in noble metal nanoparticles is due to their plasmonic reso

152 Because the surface plasmon resonances of noble metal nanoparticles offer a superior optical signa

153 The as-prepared noble metal nanoparticles on MXene show a highly sensiti

154 Noble metal nanoparticles supporting plasmonic resonance

155 which overtakes performances of previous non-noble metal nanoparticles systems, and is even better th

156 ticles systems, and is even better than some noble metal nanoparticles systems.

157 The incorporation of noble metal nanoparticles, displaying localized surface

158 ilted fiber Bragg grating (TFBG) coated with noble metal nanoparticles, either gold nanocages (AuNC)

159 Generally, the SP resonances supported by noble metal nanostructures are explained well by classic

160 Assemblies of noble metal nanostructures have unique optical propertie

161 Trapping light with noble metal nanostructures overcomes the diffraction lim

162 ctive substrates with high sensitivity using noble metal nanostructures via top-down, bottom-up, comb

163 a crystal structure of Platonic dodecahedral noble metal NCs and show that via a tailored seed-mediat

164 nary study also indicates that the assembled noble metal NCs have high catalytic activity and recycla

165 es can significantly increase the utility of noble metal NCs in basic and applied research.

166 hesized, the growth of Platonic dodecahedral noble metal NCs remains elusive.

167 Although Platonic noble metal NCs with tetrahedral, cubic, octahedral, and

168 g with Fe leads to better performance for Fe-noble metal NPs (Au, Pt, and Pd) than pristine noble met

169 arbonaceous nanomaterials, upconversion NPs, noble metal NPs (mainly gold and silver), various other

170 ble metal NPs (Au, Pt, and Pd) than pristine noble metal NPs (without Fe alloying).

171 very small Au nanoparticles (NPs) and other noble metal NPs are extraordinarily efficient.

172 etical results revealed that the position of noble metal NPs significantly influenced the coupling of

173 cross-sectional study of the microscale soft noble metal objects has been hindered by sample preparat

174 cing either a monolayer or a thin layer of a noble metal on relatively cheap core-metal nanoparticles

175 MnOx and importantly establishes that a non-noble metal oxide OER catalyst may be operated in acid b

176 les, semiconductor nanocrystals (SC NC), and noble metal particles, and we derive criteria for their

177 dulation in graphene plasmonics by employing noble metal plasmonic structures.

178 through the simultaneous reduction of GO and noble metal precursors within the GO gel matrix.

179 s have been extensively developed to replace noble metal Pt and RuO2 catalysts for the oxygen reducti

180 metal monolayers by carburizing mixtures of noble metal salts and transition metal oxides encapsulat

181 e, we show that a crystalline semiconducting noble metal sulfide, AgCuS, exhibits a sharp temperature

182 rted conflicting results on the influence of noble metal supports on the OER activity of the transiti

183 Noble metal surface plasmon polaritons have limited appl

184 y the relatively poor chemical reactivity of noble metal surfaces.

185 tic reaction pathway at various well-defined noble metal surfaces.

186 Gold is a noble metal that, in comparison with silver and copper,

187 itivities which even comparable with that of noble metal, and can be used as a biosensor for directly

188 Incorporating oxophilic metals into noble metal-based catalysts represents an emerging strat

189 research accomplished in the past decade on noble metal-based heterogeneous asymmetric hydrogenation

190 ale plasmonic array architectures to produce noble metal-based metamaterials with unusual optical pro

191 Here, the authors report N-coordinated, non-noble metal-doped porous carbons as efficient and select

192 low cost, highly active, durable completely noble metal-free electro-catalyst for oxygen reduction r

193 The identified novel noble metal-free electro-catalyst showed similar onset p

194 Hydrogen generation from water using noble metal-free photocatalysts presents a promising pla

195 This noble metal-free process follows a nature-inspired pathw

196 s among the highest reported for a molecular noble metal-free system.

197 ng an edge over conventional ones induced by noble metal.

198 er visible-light irradiation without loading noble metal.

199 metal, surrounding a core enriched with the noble metal.

200 reached without significant sintering of the noble metal.

201 rformance can rival that of state-of-the-art noble-metal and transition-metal electrocatalysts.

202 monstrating its potential as a candidate non-noble-metal catalyst for the HER.

203 ations (e.g., hydrogenation) more typical of noble-metal catalysts is an important goal.

204 his reaction has been primarily the remit of noble-metal catalysts, despite extensive work showing th

205 Unlike noble-metal catalysts, POMs are tolerant to most organic

206 nceivably be applied to other semiconductors/noble-metal catalysts, which may stand out as a new meth

207 ve way to tune and enhance the properties of noble-metal catalysts.

208 tter stability than the best-known benchmark noble-metal catalysts.

209 In some respects, large noble-metal clusters protected by thiolate ligands behav

210 have been created by incorporating complete, noble-metal complexes within proteins lacking native met

211 one of the highest HER activities of any non-noble-metal electrocatalyst investigated in strong acid,

212 n effect on Ni, similar to that observed for noble-metal electrode surfaces.

213 We report here on the first noble-metal free and covalent dye-catalyst assembly able

214 aration of mesoporous transition-metal-oxide/noble-metal hybrid catalysts through ligand-assisted co-

215 Development of a non-noble-metal hydrogen-producing catalyst is essential to

216 active support materials can help reduce the noble-metal loading of a solid chemical catalyst while o

217 plet reactors for the synthesis of colloidal noble-metal nanocrystals with controlled sizes and shape

218 Small noble-metal nanoparticles (Ag or Au) are directly synthe

219 lock-copolymer micelles and polymer-tethered noble-metal nanoparticles (NPs).

220 is due to increased electron density at the noble-metal nanoparticles, and demonstrate the universal

221 tributions of isolated or weakly-interacting noble-metal nanoparticles, as encountered in experiments

222 to precisely tune the sizes and loadings of noble-metal NPs in metal oxides.

223 d platform to clearly understand the role of noble-metal NPs in photochemical water splitting.

224 le-molecule detection possible on a range of noble-metal substrates.

225 ), MoS2 has been identified as an active non-noble-metal-based catalyst.

226 ch the performance of previously established noble-metal-based catalysts.

227 h allows for the routine bulk preparation of noble-metal-containing bifunctional nanopeapod materials

228 Studies on noble-metal-decorated carbon nanostructures are reported

229 e stable Co NPs are a promising new class of noble-metal-free catalyst for water splitting.

230 ne (TEOA) as sacrificial electron donor, the noble-metal-free complex Ni4P2 works as an efficient and

231 es (TMSs) in carbon enables the synthesis of noble-metal-free electrocatalysts for clean energy conve

232 Molybdenum sulfides are very attractive noble-metal-free electrocatalysts for the hydrogen evolu

233 The development of noble-metal-free heterogeneous catalysts that can realiz

234 This noble-metal-free method complements alternative methods

235 demonstrated to be promising alternatives to noble-metal/metal oxide catalysts for the oxygen evoluti

236 rmance in comparison to the state-of-the-art noble-metal/transition-metal and nonmetal catalysts, ori

237 r comparable to those of mostly investigated noble-metal/transition-metal catalysts (such as Pd, Pt,

238 Noble metals (for example, gold and silver) have been de

239 ion (OER) are traditionally carried out with noble metals (such as Pt) and metal oxides (such as RuO(

240 romagnetic fields to conduction electrons in noble metals and thereby can confine optical-frequency e

241 f matter of nanometer dimensions composed of noble metals are new categories of materials with many u

242 ated by surface plasmon polaritons (SPPs) in noble metals are promising for application in optoelectr

243 ate, cocatalysts based on rare and expensive noble metals are still required for achieving reasonable

244 illations of electrons and are accessible in noble metals at visible and near-infrared wavelengths, w

245 In contrast, several non-noble metals based electro-catalysts have been identifie

246 Noble metals can also be used to promote the Ni catalyst

247 Noble metals can be ionized by electrochemical corrosion

248 sed catalysts by the addition of Au or other noble metals could still represent a scalable catalyst a

249 Furthermore, nanostructures embedded with noble metals demonstrated an improved capability to effi

250 Harnessing the optical properties of noble metals down to the nanometre scale is a key step t

251 optimal materials: a ceramic substrate with noble metals for the sensing element and 3D-printed capi

252 Noble metals have also been studied and are typically fo

253 hlight the efficiency of Bi-CMEC, since only noble metals have been previously shown to promote this

254 on interactions that occur in nanostructured noble metals have offered alternative opportunities for

255 Replacement of noble metals in catalysts for cathodic oxygen reduction

256 of chemical bonding between noble gases and noble metals is addressed.

257 This includes the effect of these noble metals on the kinetics, mechanism and deactivation

258 nding of the photoluminescence mechanisms of noble metals on the nanoscale has remained limited.

259 e relative positions of the s and d bands of noble metals regulate the energy distribution and mean f

260 train-induced shifts in the d-band center of noble metals relative to the Fermi level, such splitting

261 The substitution of high-price noble metals such as Ir, Ru, Rh, Pd, and Pt by earth-abu

262 l catalyst that surpasses the performance of noble metals such as Pt.

263 by boryl transfer, a well-known reaction for noble metals such as Rh or Pt, can thus be effected by a

264 certed C-H insertion, observed with reactive noble metals such as rhodium, and stepwise radical C-H a

265 The transition from noble metals to aluminum based antenna-reactor heterostr

266 hyrin IX (Fe-PIX) proteins with abiological, noble metals to create enzymes that catalyse reactions n

267 ce energies that are lower than those of the noble metals which facilitates the growth of smooth, ult

268 symmetric hydrogenation on chirally modified noble metals will be presented.

269 xide reduction performance compared with the noble metals with a high current density and low overpot

270 ally precise self-assembled architectures of noble metals with unique surface structures are necessar

271 variety of MCs including transition metals, noble metals, and their bimetallic alloy with precisely

272 es can be extended to the synthesis of other noble metals, as the molecular mechanisms governing the

273 , such as semiconductor nanocrystals, porous noble metals, graphene, TiO2 nanotube arrays, metal-orga

274 the numerous reports on 1D nanostructures of noble metals, one-pot solution synthesis of Pt 1D nanost

275 been considered as alternative catalysts to noble metals, such as platinum, for the hydrogen evoluti

276 parent regime with speed faster than that of noble metals.

277 l catalysts due to their high utilization of noble metals.

278 into HC generation and ultrafast dynamics in noble metals.

279 n be significantly improved by incorporating noble metals.

280 aluminium and by the crystal orientation for noble metals.

281 ntense search for plasmonic materials beyond noble metals.

282 that lack the high intrinsic activity of the noble metals.

283 nocomposites for biosensing are formed using noble metals.

284 hylene selectivities can be achieved without noble metals; conversion and selectivity on Fe3O4 are st

285 monics research has traditionally focused on noble metals; however, any material with a sufficiently

286 NOBLE provides a term-to-concept matching system suitabl

287 d metabolomics approach, we demonstrate that noble rot alters the metabolism of cv Semillon berries b

288 ite-skinned berries, was a common outcome of noble rot and red-skinned berry ripening.

289 , the results of this work demonstrated that noble rot causes a major reprogramming of berry developm

290 We finally characterized the impact of noble rot in botrytized wines.

291 of anthocyanins is a consistent hallmark of noble rot in cv Semillon berries.

292 The evaluation of Botrytis cinerea as noble rot on withered grapes is of great importance to p

293 Unlike bunch rot, noble rot promotes favorable changes in grape berries an

294 Noble rot results from exceptional infections of ripe gr

295 rst proteomic analysis of grapes infected by noble rot under withering conditions to identify possibl

296 During noble rot, B. cinerea induced the expression of key regu

297 Noble rot-infected berries of cv Semillon, a white-skinn

298 acid aroma precursors also increased during noble rot.

299 On two benchmarking tasks, NOBLE's performance exceeded commonly used alternatives,

300 from bulk crystals, a pentagonal 2D layered noble transition metal dichalcogenide with a puckered mo