ライフサイエンスコーパス: tungsten

1 ation mechanism in nanoscale crystals of BCC tungsten.

2 roughening were observed in the cold rolled tungsten.

3 or two different grades of ultrafine-grained tungsten.

4 gue resistance compared to severely deformed tungsten.

5 ition by axially grading the doping level of tungsten.

6 ion in the gold and d wave-like modes in the tungsten.

7 wder-route production of bulk nanostructured tungsten.

8 ), with the metal being either molybdenum or tungsten.

9 and tungsten and tup only in the presence of tungsten.

10 oenzymes while formate dehydrogenase prefers tungsten.

11 ce and Fermi-velocity distribution vF(kF) of tungsten.

12 roximately -0.5 by incorporating oxygen into tungsten.

13 balt (0.5-6 nM), molybdenum (10-5600 nM) and tungsten (0.3-8 nM) in Hydrate Ridge sediment porewaters

14 ich is much smaller than that of alpha-phase tungsten (174 Wm(-1)K(-1)).

15 ion, we assessed functional neurotoxicity of tungsten, a common microelectrode material, and two cond

16 dynamic stability and magnetic properties of tungsten adsorbed tri-vacancy fluorinated (TVF) graphene

17 The tungsten alkylidene can be manipulated in air, deliverin

18 n of the new CF(3)-ONO(3-) trianionic pincer tungsten-alkylidene [CF(3)-ONO]W horizontal lineCH(Et)(O

19 tic strategy to create enhanced nucleophilic tungsten-alkylidene and -alkylidyne complexes.

20 The tungsten alkylidyne [(t)BuOCO]W identical withC((t)Bu) (

21 The tungsten alkylidyne [CF3-ONO]W identical withCC(CH3)3(TH

22 Tungsten alkylidynes [CF3-ONO]W identical withCC(CH3)3(T

23 l is applied to design stable nanostructured tungsten alloys.

24 lium antimonide cell paired with a broadband tungsten and a radiatively-optimized Drude radiator are

25 materials are picked out, but also titanium, tungsten and boron carbides, as well as carbide-derived

26 t a novel ex-situ method to codope TiO2 with tungsten and carbon (W, C) by sequentially annealing W-p

27 ments used in high-temperature alloys (e.g., tungsten and molybdenum), to vulnerability to supply res

28 is of pi/pi* orbital energy matching between tungsten and organic PE fragments and the introduction o

29 igands within complexes based on molybdenum, tungsten and ruthenium has led to reactivity and selecti

30 hich possess multiple bond character between tungsten and silicon.

31 g mod in the presence of both molybdenum and tungsten and tup only in the presence of tungsten.

32 tals known to be used (cobalt, iron, nickel, tungsten and zinc; 83 peaks) plus metals the organism wa

33 Molybdenum, antimony, tungsten, and uranium were positively associated with di

34 Molybdenum, antimony, tungsten, and uranium were positively associated with di

35 esium, molybdenum, lead, antimony, thallium, tungsten, and uranium with diabetes prevalence.

36 Molybdenum-, tungsten-, and ruthenium-based complexes that control th

37 )(2)(IMes)H with KH and 18-crown-6 gives the tungsten anion [CpW(CO)(2)(IMes)](-)[K(18-crown-6)](+).

38 A series consisting of a tungsten anion, radical, and cation, supported by the N-

39 The trace elements molybdenum and tungsten are essential components of cofactors of many m

40 e linked in parallel serpentine arrays, with tungsten atoms in between.

41 The codeposition of laser-ablated tungsten atoms with neat hydrogen at 4 K forms a single

42 By selectively substituting tungsten atoms with tantalum, the Vickers hardness can b

43 f the Z isomer owing to control induced by a tungsten-based alkylidene.

44 It is shown that the power output of a tungsten-based device increases by 6.5% while the cell t

45 The key limiting factors for the Drude- and tungsten-based devices are respectively the recombinatio

46 eous thermal plasmon emission, we engineer a tungsten-based thermal emitter, fabricated in an industr

47 s into a polyoxometalate cage, a new type of tungsten-based unconventional Dawson-like cluster, [W18O

48 d graphene (G) sandwiched between beta-phase tungsten (beta-W) films of 15, 30 and 40 nm thickness.

49 bunit of this complex harbors an active site tungsten-bis-pyranopterin cofactor with the metal being

50 pening process was efficiently promoted by a tungsten/bis(hydroxamic acid) catalytic system, furnishi

51 This process was promoted by a tungsten-bishydroxamic acid complex at room temperature

52 (La/Ce)6 octahedra, reminiscent of hexagonal tungsten bronzes, with planar Si6 rings enclosed within

53 Fluorinated tungsten calix[4]arene imido complexes were synthesized

54 esize a series of mononuclear molybdenum and tungsten calixarene compounds that feature both coordina

55 sted that non-3d high-valency metals such as tungsten can modulate 3d metal oxides, providing near-op

56 pported tungsten carbide (WC) and molybdenum tungsten carbide (Mo(x)W(1-x)C) nanoparticles are highly

57 Carbon-supported tungsten carbide (WC) and molybdenum tungsten carbide (M

58 For tungsten carbide - epoxy crystals we identify all angle

59 Tungsten carbide cobalt (WC-Co) matrix nanocomposites re

60 Supported tungsten carbide is an efficient and vital nanomaterial

61 n plastic blocks, cured and sectioned with a tungsten carbide knife to obtain mineralized bone sectio

62 Consequently, tungsten carbide may be a promising catalyst in self-hyd

63 Tungsten carbide nanorods (WC NRs) are demonstrated for

64 ing OH* are significantly more endergonic on tungsten carbide than on platinum.

65 In this work, tungsten carbide with tube-like nanostructures (WC NTs)

66 Au); the low-cost carbide substrate includes tungsten carbides (WC and W(2)C) and molybdenum carbide

67 by the similar bulk electronic properties of tungsten carbides to Pt, as is supported by density func

68 have solved this challenge and now report a tungsten catalyst supported by a tetraanionic pincer lig

69 n-to-air atmosphere between a solid pin type tungsten cathode and a liquid drop placed on a graphite

70 addition to these conserved properties, the tungsten centers endow OPEs with reversible one-electron

71 of specific neutral organic molecules to the tungsten centers induces an upfield shift of the fluorin

72 n 3-center-2-electron interactions with both tungsten centers.

73 Here, we show that a tungsten centre can be used to cleave a strong C-C bond

74 intravenous administration of iodinated and tungsten cluster contrast media.

75 Tungsten coil atomic emission spectrometry is an ideal t

76 the bulk of the blackbody emission from the tungsten coil is blocked.

77 The tungsten coil is extracted from an inexpensive 24 V, 250

78 bank of 9 solid-state detector columns with tungsten collimators that rotate independently.

79 Compound I is red and the tungsten complex II is blue as a result of intense metal

80 Our investigations indicate that tungsten complexes are inactive in the test reaction eit

81 The free energies interconnecting nine tungsten complexes have been determined from chemical eq

82 nyl isocyanide (CNdipp) have been developed; tungsten complexes incorporating these oligoarylisocyani

83 The homoleptic arylisocyanide tungsten complexes, W(CNXy)6 and W(CNIph)6 (Xy = 2,6-dim

84 of the valley polarization as a function of tungsten concentration, where 40% tungsten incorporation

85 ming contaminated cabbage accumulated higher tungsten concentrations relative to the concentrations d

86 ions of climbing prismatic loops in iron and tungsten, confirming that this novel form of vacancy-fre

87 but analogous to all of the currently known tungsten-containing enzymes.

88 Proteins affiliated with the tungsten-containing form of formylmethanofuran dehydroge

89 t work, we conclude that all molybdenum- and tungsten-containing formate dehydrogenases and related e

90 lectively, and efficiently interconverted by tungsten-containing formate dehydrogenases that surpass

91 x chemistry, and excited-state properties of tungsten-containing oligo-phenylene-ethynylenes (OPEs) o

92 in affinity is reflected in a lower cellular tungsten content in a cj1540 (tupA) mutant compared with

93 for solid solutions of tungsten in ReB2 with tungsten content up to a surprisingly large limit of nea

94 along both the a- and c-axes with increasing tungsten content, as evaluated by powder X-ray and neutr

95 e dependent upon the defective nature of the tungsten-deficient metal sublattice.

96 It was observed that cold rolled tungsten demonstrated better power handling capabilities

97 Tungsten diboride (WB2), which takes a structural hybrid

98 In particular, for Tungsten dichalcogenides it has been found that the sign

99 leveraging the atomically thin semiconductor tungsten diselenide (WSe2) as a host for quantum dot-lik

100 ily such as molybdenum disulphide (MoS2) and tungsten diselenide (WSe2), as well as other emerging tw

101 operties of mono and few-layer TMDs, such as tungsten diselenide (WSe2), by controlling the defects,

102 e exciton homogeneous linewidth in monolayer tungsten diselenide (WSe2).

103 de (MoS2), molybdenum diselenide (MoSe2) and tungsten diselenide (WSe2).

104 ic arrays of hundreds of quantum emitters in tungsten diselenide and tungsten disulphide monolayers,

105 ngle-photon emission from localized sites in tungsten diselenide and tungsten disulphide.

106 y thin crystalline semiconductor--that is, a tungsten diselenide monolayer--is non-destructively and

107 We found that tungsten diselenide nanoflakes show a current density of

108 ron-hole pairs in the layered dichalcogenide tungsten diselenide while a strong terahertz field accel

109 hat are spatially localized by defects in 2D tungsten-diselenide (WSe2) monolayers.

110 Here, the growth of oxidation-resistant tungsten disulfide (WS2 ) monolayers on graphene is demo

111 MDs) such as molybdenum disulfide (MoS2) and tungsten disulfide (WS2) are envisioned to present unpre

112 Tungsten disulfide (WS2) MWNTs, ~300 nm in diameter and

113 Here we show that with a tungsten disulfide (WS2) substrate, the strength of the

114 nally large Bloch-Siegert shift in monolayer tungsten disulfide (WS2) under infrared optical driving.

115 also demonstrate that optical properties of tungsten disulfide can be effectively tuned by carriers

116 Here we show, using graphene-tungsten disulfide heterostructures as an example, evide

117 nsfer at a 2D/0D heterostructure composed of tungsten disulfide monolayers (2D-WS2) and a single laye

118 The cytotoxicity of tungsten disulfide nano tubes (INT-WS2) and inorganic fu

119 a comprehensive wetting study of individual tungsten disulfide nanotubes by water.

120 tion processed, optically uniform, few-layer tungsten disulfide saturable absorber (WS2-SA).

121 We find that photocarriers injected in tungsten disulfide transfer to graphene in 1 ps and with

122 nergy of oxygen molecules on graphene and 2D tungsten disulfide using temperature-programmed terahert

123 nic gating in individual chiral nanotubes of tungsten disulfide.

124 Especially, single-layer tungsten disulfides (WS2) is a direct band gap semicondu

125 oxygen molecules on graphene ( 0.15 eV) and tungsten disulphide ( 0.24 eV).

126 mb, leading to grain boundary migration in a tungsten disulphide monolayer.

127 quantum emitters in tungsten diselenide and tungsten disulphide monolayers, emitting across a range

128 We show that intrinsic defects in tungsten disulphide play an important role in this proxi

129 tunnelling transistors where two-dimensional tungsten disulphide serves as an atomically thin barrier

130 f monolayer molybdenum disulphide (MoS2) and tungsten disulphide, grown directly on insulating SiO2 s

131 olayer graphene and few-layer semiconducting tungsten disulphide.

132 significant grain boundary reconstruction in tungsten disulphide.

133 m localized sites in tungsten diselenide and tungsten disulphide.

134 Tungsten ditelluride (WTe2) is a transition metal dichal

135 by analyzing the self-cleaning properties of tungsten doped anatase as an example.

136 Tungsten doped titanium dioxide films with both transpar

137 delivery of a high-voltage nsEP to cells by tungsten electrodes creates a multitude of biophysical p

138 olybdenum encoded by modABC and a second for tungsten encoded by tupABC.

139 g the three major mononuclear molybdenum and tungsten enzyme families, and that binding-site micro-tu

140 nopterin dithiolene ligand in molybdenum and tungsten enzymes could participate in catalysis through

141 ein structures of mononuclear molybdenum and tungsten enzymes.

142 tanium ethoxide and dopant concentrations of tungsten ethoxide at 500 degrees C from a toluene soluti

143 ntation of transformed Escherichia coli with tungsten facilitated the replacement of molybdenum in re

144 Here, we show that a plain incandescent tungsten filament (3,000 K) surrounded by a cold-side na

145 While the incorporation of oxygen into the tungsten films leads to significant changes in their mic

146 he results show that graphene inserted among tungsten films plays a dominant role in reducing radiati

147 energy landscape for self climb in iron and tungsten, finding a simple, material independent energy

148 affinity tungstate transporter that supplies tungsten for incorporation into FDH.

149 al diffusivity measurements in ion-implanted tungsten for nuclear fusion armour.

150 One of the most interesting materials is tungsten, for which large spin-orbit torques have been f

151 Tungsten-graphene multilayer composites are fabricated u

152 For the case of one-third of a monolayer of tungsten grown by atomic layer deposition on a hematite

153 Tungsten has been chosen as the main candidate for plasm

154 Metallic tungsten has civil and military applications and was con

155 , promethium, and samarium), cobalt, silver, tungsten, heavy rare earth elements (yttrium, europium,

156 water insoluble vibrational dynamics probe, tungsten hexacarbonyl (W(CO)6), is located in the alkane

157 symmetric CO stretch of a vibrational probe, tungsten hexacarbonyl (W(CO)6).

158 The antisymmetric CO stretch of tungsten hexacarbonyl was used as a vibrational probe an

159 f zirconium hydride, probably facilitated by tungsten hydride which was formed at this temperature.

160 d, forming Cp*W(CO)(2)(H)(C(5)H(11)-Bpin), a tungsten-hydride complex containing a weakly bound alkyl

161 onding and size-selectivity of calix[4]arene tungsten-imido complex combined with (19)F NMR spectrosc

162 tionally guided design involving high-purity tungsten in a precisely fabricated photonic crystal slab

163 ure can be maintained for solid solutions of tungsten in ReB2 with tungsten content up to a surprisin

164 nt equations of state of gold, platinum, and tungsten in static experiments up to 500 gigapascals.

165 ly, synchrotron mapping provided evidence of tungsten in the inner layer of the snail shell, suggesti

166 re assayed in the presence of molybdenum and tungsten in wild-type and mod and tup backgrounds.

167 unction of tungsten concentration, where 40% tungsten incorporation is sufficient to achieve valley p

168 nolytic cleavage of epothilone B followed by tungsten-induced deoxygenation of the epoxide moiety.

169 erindithiolene chelation in the basal plane, tungsten instead of the native metal molybdenum was empl

170 ntity of the sixth ligand of the active-site tungsten ion together with the interplay of the electron

171 pyranopterin cofactors rather than from the tungsten ion.

172 udies reveal a synergistic interplay between tungsten, iron, and cobalt in producing a favorable loca

173 Syntheses of five types of tungsten-iron-sulfur/selenium clusters, namely, incomple

174 Tungsten is a promising plasma facing material for fusio

175 rmed electrical nanocontact between gold and tungsten is a prototypical junction between metals with

176 Although tungsten is currently considered the most promising cand

177 6 parts per million, 2 standard deviations) tungsten isotope analyses of these rocks, here we show t

178 New tungsten isotope data for modern ocean island basalts (O

179 Here, using molybdenum and tungsten isotope measurements on iron meteorites, we dem

180 iation relies on highly precise and accurate tungsten isotope measurements.

181 Tungsten isotopic data for Kostomuksha komatiites dated

182 High-precision tungsten isotopic data from rocks from two large igneous

183 The tungsten isotopic data negatively correlate with (3)He/(

184 u, reveal preservation to the Phanerozoic of tungsten isotopic heterogeneities in the mantle.

185 to dramatically affect the microstructure of tungsten, leading to bubble growth, blistering, and/or t

186 ilm of anatase TiO(2) doped with an array of tungsten levels as a solid solution ranging from 0.38-13

187 he system is validated using measurements of tungsten light and a static scene.

188 Despite low levels of cobalt and tungsten, metagenomic and metaproteomic data suggest tha

189 photocathodes are synthesized by evaporating tungsten metal in an ambient of ethylene gas to form tun

190 tendril surfaces, but tendrils were all BCC tungsten metal.

191 Tungsten microelectrodes were inserted percutaneously in

192 assette was introduced into callus cells via tungsten microparticles, and stable transformants were s

193 The dynamics of gold-tungsten microwires were manipulated using an automated

194 Tungsten microwires with nanoscale tips are insulated ex

195 -density polyethylene (HDPE) moderation, and tungsten moderation.

196 Molybdenum or tungsten monoaryloxide pyrrolide (MAP) complexes that co

197 observed when ((tBu)PCP)IrH2 was paired with tungsten monoaryloxide pyrrolide complexes such as W(NAr

198 In tungsten monoboride (WB), the boron atoms are linked in

199 hermore, the Pt substrate can be replaced by tungsten monocarbide to achieve similar activity and sel

200 Tungsten nanofibers are recognized as biologically poten

201 We have grown tungsten nanotendrils at low (50 eV) and high (12 keV) H

202 cribed, which applies high voltage between a tungsten nanotip and a metal plate to generate a plasma

203 strate the synthesis of Pt shell on titanium tungsten nitride core nanoparticles (Pt/TiWN) by high te

204 Tungsten nitrido complexes of the form WN(NR2)3 [R = com

205 the superhard metals, the highest boride of tungsten--often referred to as WB4 and sometimes as W(1-

206 ns of aromatic ligands eta(2)-coordinated to tungsten or molybdenum and the use of these reactions in

207 ith 1T' structure, namely, 1T'-MX2 with M = (tungsten or molybdenum) and X = (tellurium, selenium, or

208 m, manganese, iron, cobalt, molybdenum (Mo), tungsten, or rhenium.

209 Tantalum-doped tungsten oxide (Ta-WO x )/conjugated polymer multilayers

210 surfaces by electrodeposition of nanoporous tungsten oxide (TO) films.

211 Zirconia-supported tungsten oxide (WO(x)/ZrO(2)) is considered an important

212 by a porous shell growing at the surface of tungsten oxide and shielding the wire surface from flowi

213 greater than found for bulk WO(3), supported tungsten oxide catalysts, and even the highly acidic WO(

214 the fabrication of thick, vertically aligned tungsten oxide nanochannel layers, with pore diameter of

215 first sensing film consists of self-ordered tungsten oxide nanodots, limiting the response kinetics

216 ossibility of rationally designing plasmonic tungsten oxide nanoparticles for light harvesting, bioim

217 ond modality is a three-dimensional array of tungsten oxide nanotubes, which in turn involves both th

218 rs, considerable attention has been given to tungsten oxide with a band gap of E(g) approximately 2.6

219 contrast to what happens in materials (like tungsten oxide) susceptible to ionic electromigration an

220 e report an approach to synthesize molecular tungsten-oxide-based pentagonal building blocks, in a ne

221 and 11-oxa-benzonorbornadienes with a single tungsten oxo alkylidene catalyst, W(O)(CH-t-Bu)(OHMT)(Me

222 those of the parent imido derivative and its tungsten oxo analogue.

223 Treating 3 with acid chlorides provides the tungsten oxo chloride species [CF3-ONO]W(O)Cl (4) and di

224 ast to the chemical inertness of mononuclear tungsten oxo species, 2 undergoes a four-electron reduct

225 lowed by migratory insertion to generate the tungsten-oxo alkylidene 2.

226 catalyze isobutylene expulsion to yield the tungsten-oxo complex [CF(3)-ONO]W(O)((n)Pr) (6).

227 ious carbonyl-containing substrates provides tungsten-oxo-vinyl complexes upon oxygen atom transfer.

228 w AsPNMes* ligand, which when complexed with tungsten pentacarbonyl elicits extrusion of the (AsP)W(C

229 Furthermore, the performance of different tungsten period-thicknesses in radiation tolerance is sy

230 ssembled templates to fabricate high-quality tungsten photonic crystals that demonstrate unprecedente

231 pography, leading to surface degradation, of tungsten plasma-facing fusion reactor walls.

232 ardment under tokamak-relevant conditions on tungsten plasma-facing materials in a magnetic fusion en

233 in characterizing the mechanical behavior of tungsten polycrystalline samples with ion-irradiated sur

234 illa was marked with a radiodense mixture of tungsten powder and temporary cement.

235 implications of sodium tungstate and an aged tungsten powder-spiked soil containing monomeric and pol

236 While the snail significantly bioaccumulated tungsten, predominately in the hepatopancreas, cabbage l

237 allium (Ptrend = 0.13), 2.18 (1.51-3.15) for tungsten (Ptrend < 0.01), and 1.46 (1.09-1.96) for urani

238 tion with the Drude radiator outperforms the tungsten radiator, dominated by frustrated modes, only f

239 CO)(2)(IMes)(MeCN)](+) gives the 17-electron tungsten radical CpW(CO)(2)(IMes)(*).

240 ocks, here we show that they have a isotopic tungsten ratio (182)W/(184)W that is significantly highe

241 nium-182 in mantle domains with high hafnium/tungsten ratios, were created during the first ~50 milli

242 itation to collect particles on the tip of a Tungsten rod, and subsequently, by flowing liquid over t

243 s in stereoretentive olefin metathesis using tungsten, ruthenium, and molybdenum catalysts are presen

244 metal in an ambient of ethylene gas to form tungsten semicarbide (W2C) thin films on top of p-type s

245 Further analysis by tungsten-shadowing EM revealed striking differences in t

246 ost promising elemental materials, including tungsten, silicon, graphite, diamond and graphene, for p

247 ergy CT was performed in a set of iodine and tungsten solution phantoms and in a rabbit in which iodi

248 Well-defined surface organometallic tungsten species can be designed to implement targeted f

249 ree dialkylamines from monomeric and dimeric tungsten species.

250 can also transport tungsten, while tup is a tungsten-specific transporter.

251 A hollow tungsten sphere was interrogated to evaluate the respons

252 The absolute configuration of the tungsten stereocenter in TpW(NO)(PMe3)(eta(2)-benzene) c

253 n ultra-thin bilayer of copper and amorphous tungsten suboxide, which derives its remarkable optical

254 on activity and selectivity as a function of tungsten surface density, catalyst support type, and cal

255 lation follows a volcano-shape dependence on tungsten surface density.

256 Characterization of the hafnium-tungsten systematics ((182)Hf decaying to (182)W and emi

257 cused attention on the supply chains of tin, tungsten, tantalum, and gold (3TG), specifically those o

258 The model estimates the upper bound of tin, tungsten, tantalum, and gold use within ICT products to

259 Tungsten tetraboride (WB(4)) is an interesting candidate

260 To enhance the hardness of tungsten tetraboride (WB(4)), a notable lower cost membe

261 Alloys of tungsten tetraboride (WB4) with the group 4 transition m

262 Tungsten tetraboride alloys with a variable concentratio

263 Tungsten tetraboride is an inexpensive, superhard materi

264 ign future compounds stable in the adaptable tungsten tetraboride structure.

265 Powders of tungsten tetraboride with and without 1 at.% Re addition

266 ce that crystallize in the same structure as tungsten tetraboride.

267 , nanochannels, nanopores) on metals such as tungsten that up to now were regarded as very difficult

268 Similar to beta-tantalum and beta-tungsten, the sputter-grown V films also have a high res

269 Both layers were grown on a sharp tungsten tip by chemical vapor deposition (CVD) in a ste

270 anning tunnelling microscopy with a standard tungsten tip.

271 nts at separate points inside the reactor, a tungsten/titanium compositional gradient was formed and

272 kel, molybdenum, ruthenium to palladium, and tungsten to platinum in the periodic table.

273 the spin texture in iron/nickel bilayers on tungsten to show that chiral domain walls of mixed Bloch

274 comparisons to observations of the motion of tungsten tracers in the film.

275 enes encoding a high-affinity molybdenum and tungsten transporting system and (ii) repressors of gene

276 oO(3) ), vanadium pent-oxide (V(2) O(5) ) or tungsten tri-oxide (WO(3) ) have been extensively studie

277 aring inorganic oxide semiconductors such as tungsten trioxide (WO3) for photovoltaic or photocatalyt

278 the structural and electronic properties of tungsten trioxide (WO3) surfaces interfaced with an IrO2

279 classical but inert transition metal oxide, tungsten trioxide, to be an efficient electrocatalyst fo

280 traalkyl, tantalum trisalkyl-alkylidene, and tungsten trisalkyl-alkylidyne complexes).

281 Platinum (Pt), platinum black (Pt Bl), tungsten/tungsten oxide (W/WO3) and iridium oxide (Pt/Ir

282 on of ultrafine- and nanocrystalline-grained tungsten under conditions similar to those in a reactor,

283 We find tin and tungsten use in automobiles to be 3-5 times higher than

284 Most molybdenum(VI) and tungsten(VI) dioxoazides were fully characterized by the

285 Molybdenum(VI) and tungsten(VI) dioxodiazide, MO2(N3)2 (M=Mo, W), were prep

286 A series of novel molybdenum(V) and tungsten(VI) oxoazides was prepared starting from [MOF4

287 Most molybdenum(V) and tungsten(VI) oxoazides were fully characterized by their

288 ray photoelectron spectroscopy, the as-grown tungsten(VI) sub-oxide was identified as monoclinic W18O

289 ly tested on short-lived molybdenum (Mo) and tungsten (W) isotopes to the preparation of a carbonyl c

290 vity with decreasing width in single crystal tungsten (W) nanowires having a height of 21 nm.

291 ve evaluated the effect of titanium (Ti) and tungsten (W) oxide nanoparticles on the diazotrophic gro

292 lds on previous studies on military-relevant tungsten (W) to more thoroughly explore environmental pa

293 , iridium (Ir)/niobium (Nb) and iridium (Ir)/tungsten (W) was examined.

294 ading candidate for plasma-facing materials, tungsten (W), in future nuclear fusion reactors.

295 lybdenum transporter that can also transport tungsten, while tup is a tungsten-specific transporter.

296 direction were achieved by scanning a 4 mum tungsten wire target.

297 In our previous work, gold-tungsten wires (25 mum in diameter) were functionalized

298 Gold tungsten wires (O: 50 mum) coated with polyethylenimine

299 phological transformations of the surface of tungsten wires in a specially designed electrochemical c

300 nd bis-terphenyl complexes of molybdenum and tungsten with general composition M2(Ar')(O2CR)3 and M2(