ライフサイエンスコーパス: tin

1 l bond between a transition metal (TM) and a tin atom, are very promising due to their ability in med

2 e relative standard deviation was 4.5% for a tin solution of 0.50microgL(-1).

3 This effect arises from a tin oxide surface layer that encapsulates small Pd-rich

4 n of 1 with ethyl diazoacetate resulted in a tin-substituted ketene complex [Cp*(IXy)(H)2 RuSn(OC2 H5

5 part from the pipetting of the sample into a tin foil cup, which is placed in the carousel of the EA.

6 ation of the microstructural evolutions of a tin electrode in a lithium-ion battery during cycling is

7 igations on the well-preserved contents of a tin pyxis discovered onboard the Pozzino shipwreck (seco

8 his study, we report the identification of a tin(IV) oxochloride-derived cluster that binds an evolut

9 went dual-energy CT (90 kV and 150 kV with a tin filter) and 3-T magnetic resonance (MR) imaging.

10 how that an ionic liquid can be pumped along tin dioxide, silicon or zinc oxide nanowires as a thin p

11 of indium acetylacetonate, In(acac)(3), and tin bis(acetylacetonate)dichloride, Sn(acac)(2)Cl(2), at

12 lving the following factors: nitric acid and tin chloride concentrations and sample flow rate.

13 sordered monolayers consisting of alkyls and tin oxide.

14 od for preconcetration of trace antimony and tin in beverage samples.

15 was carried out in the presence of base and tin(II) acetate.

16 [111] and [110] superlattices of calcium and tin tellurides.

17 and the smelting of lead, zinc, copper, and tin sulfides are sources of indium to the atmosphere in

18 erful discharges, some grains are heated and tin diffuses in the large silicon crystals.

19 pical silane, lithium aluminium hydride, and tin-based conditions for these reductions.

20 the bulky, two-coordinate germanium(II) and tin(II) hydride complexes, L(dagger)(H)M: (M = Ge or Sn,

21 th DHCR24 and HO-1 small interfering RNA and tin-protoporphyrin-IX treatment abolished these effects.

22 al cells with HO-1 small interfering RNA and tin-protoporphyrin-IX treatment did not inhibit the (A-I

23 Alloy-type anodes such as silicon and tin are gaining popularity in rechargeable Li-ion batter

24 materials such as lithium metal, silicon and tin as anodes, and sulphur and oxygen as cathodes.

25 emission spectroscopy shows that silicon and tin melt almost simultaneously.

26 esis of separate nanocrystals of silicon and tin with average sizes of 10 nm.

27 tal oxide film--indium tin oxide or antimony tin oxide--coated with a thin outer shell of TiO2 formed

28 High surface area tin oxide nanocrystals prepared by a facile hydrothermal

29 port the application of a high-surface-area, tin-doped indium oxide electrode surface-derivatized wit

30 degrees C, comparable with state of the art tin-doped indium oxide coatings deposited from nanocryst

31 t of lead with nontoxic alternatives such as tin has been demonstrated in bulk films, but not in spat

32 xistence of more substantial binding between tin and chlorine in comparison to the triflate substitue

33 he order of DeltaT ~ 0.15 K compared to bulk tin has been observed for 40% volume fraction of barium

34 Inhibition of HO-1 by tin protoporphyrin (SnPP) or siRNA downregulated Pax3/7-

35 arting from 17e; Scheme 9 ), both derived by tin-lithium exchange, and 24 (starting from 20; Scheme 9

36 hy to define the sensor geometry followed by tin sputtering.

37 lting alpha,beta-enone, which is mediated by tin(IV) chloride in the presence of N-phenylselenophthal

38 n of the known Ni-centered and Ni(CO)-capped tin clusters [Ni@Sn9 Ni(CO)](3-) .

39 In all cases, tin oxide is codeposited in submonolayer amounts.

40 able performance is also achieved for cesium tin iodide solar cells with en loading, demonstrating th

41 With this approach, it is possible to change tin nucleation from a stochastic to a deterministic proc

42 face plasmon resonances (LSPRs) in colloidal tin-doped indium oxide (Sn:In2O3, or ITO) nanocrystals.

43 mations even when compared with conventional tin-based catalysts (dibutyltin dilaurate) or 1,8-diazab

44 reported to date and a linearly coordinated tin atom.

45 n-Cl bond of the trigonal-planar-coordinated tin center.

46 A new wurtzite phase of copper tin selenide (CTSe) was discovered, and the resulting na

47 in the ternary nanocrystal system, dicopper tin triselenide.

48 ilized the metal particles on antimony-doped tin oxide (ATO) in sustained lower Ir oxidation states (

49 tic water oxidation occurs at fluoride-doped tin oxide (FTO) electrodes that have been surface-modifi

50 In this study, we prepare fluorine doped tin oxide (FTO) films by chemical vapor deposition with

51 ne/gold nanoparticles (AuNPs)/fluorine doped tin oxide (FTO) glass electrode.

52 alladium (ZnO/Pt-Pd) modified fluorine doped tin oxide (FTO) glass plate was fabricated for detection

53 (rGO) nanocomposite modified fluorine doped tin oxide (FTO).

54 cell, utilizes a transparent fluorine doped tin oxide electrode to sense O2.

55 rys zeo were deposited on the Fluorine doped tin oxide glass electrode (FTO) by drop-casting method f

56 tion of pyrene pyrrole onto a fluorine-doped tin oxide (FTO) electrode allowed the targeted orientati

57 on a glass slide covered with fluorine-doped tin oxide (FTO), which acts as a biosensor.

58 Illumination of the resulting fluorine-doped tin oxide (FTO)|SnO2/TiO2|-[Ru(a) (II)-Ru(b) (II)-OH2](4

59 solvothermally on conductive fluorine-doped tin oxide substrates.

60 by drop-casting 1a in DCM on fluorine-doped tin oxide, and the ECL of the 1a film was found in phosp

61 Spiro-OMeTAD/Au, where FTO is fluorine-doped tin oxide, sTiO2 indicates solid-TiO2, and mpTiO2 is mes

62 solar cells grown directly on fluorine-doped tin oxide-coated substrates without using any hole-block

63 at 300 to 773 kelvin, realized in hole-doped tin selenide (SnSe) crystals.

64 be required for the development of economic tin deposits, are marked by zircon Eu/Eu* values of ca.

65 onductors, but also for 'opaque' electrodes, tin-doped indium oxide and silver nano-films.

66 We find tin and tungsten use in automobiles to be 3-5 times high

67 The synthesis of the first tin-bridged bis(benzene) vanadium and trovacene sandwich

68 Five tin oxide-based Taguchi Gas Sensors were applied in the

69 cy is one of the highest reported so far for tin halide perovskite systems, highlighting potential ap

70 Here we identify a family of nucleants for tin, prove their effectiveness using a novel droplet sol

71 s: first, the +2 and +4 oxidation states for tin are relatively stable; in addition, the phase of the

72 lead (Pb)-free inverted planar formamidinium tin triiodide (FASnI3 ) perovskite solar cells (PVSCs) a

73 pia (Oreochromis spp.) sampled from a former tin mining pool, concrete tank and earthen pond in Jeleb

74 red tilapia can be ranked as follows: former tin mining pool > concrete tank > earthen pond.

75 -silica molecular sieve containing framework tin (Sn-Beta) to produce the Diels-Alder dehydration pro

76 as a superior dopant-free HTL for lead-free tin-based perovskite solar cells.

77 Here, we report lead-free tin-based solar cells with greatly enhanced performance

78 Narrow band gap tin(II) chalcogenide (SnS, SnSe, SnTe) nanocrystals are

79 of silylene 1 and for its heavier germanium, tin, and lead homologues uniformly electronic structures

80 le and triple bonds with silicon, germanium, tin and lead had considerable impact on modern ideas of

81 eolite-like chalcogenides based on germanium/tin remained unknown, even after decades of research.

82 rinuclear omplex is reactive toward TEMPO-H, tin hydrides, thiols, and dihydrogen.

83 g-opening polymerization of the heteroleptic tin-bridged [1]trovacenophane using Karstedt's catalyst

84 his issue, here we report a new hierarchical tin/carbon composite in which some of the nanosized Sn p

85 Here six crystalline high-germanium or high-tin zeolite-type sulfides and selenides with four differ

86 The reduced tillering in tin is due to early cessation of tiller bud outgrowth du

87 Indium tin oxide (ITO) nanoparticles were spray-coated on trans

88 of NiO nanoparticles deposited on an indium tin oxide (ITO) coated glass substrate serves as an effi

89 gold nanoparticle (AuNP) arrays on an indium tin oxide (ITO) electrode using efficient and low-cost m

90 ide (Fe3O4) nanodots fabricated on an indium tin oxide (ITO) substrate via a block copolymer template

91 controlled potential coulometry in an indium tin oxide (ITO) thin-layer electrochemical cell.

92 An indium tin oxide (ITO) transparent electrical heater is pattern

93 We demonstrate Mn CSV using an indium tin oxide (ITO) working electrode both bare and coated w

94 utral morpholino capture probes on an indium tin oxide (ITO)-coated glass slide.

95 0) cm(-2) at the interface between an indium tin oxide anode and the common small molecule organic se

96 oparticles (NPs) at the surface of an indium tin oxide electrode.

97 In arrays of gold nanoparticles on an indium tin oxide substrate and arrays of 100-nanometer-diameter

98 ids generated by photochemistry at an indium tin oxide-coated substrate.

99 ovskite solar-cell devices made on an indium tin oxide/poly(ethylene terephthalate) substrate via a l

100 ade from graphene (at the bottom) and indium tin oxide (at the top) for dielectrophoretic cell trappi

101 Indium and indium tin oxide (ITO) are extensively used in electronic techn

102 Silver (Ag) metal and indium tin oxide (ITO) are used for the fabrication of the SPR

103 consists of nanostructured silver and indium tin oxide (ITO) electrodes which are separated by 5 nm t

104 Gold and indium tin oxide electrodes were characterized with respect to

105 to glassy carbon, gold, platinum, and indium tin oxide surfaces.

106 n other transparent materials such as indium tin oxide ( approximately 80%) and ultrathin metals ( ap

107 ent conducting oxides (TCOs), such as indium tin oxide and zinc oxide, play an important role as elec

108 z, and to conductor supports, such as indium tin oxide, aluminum, highly ordered pyrolytic graphite,

109 he electron injection barrier between indium tin oxide (ITO) and C70 by 0.67 eV.

110 omposite thin film sandwiched between indium tin oxide and indium-gallium eutectic alloy exhibit a lo

111 ensitized photocathodes on NiO-coated indium tin oxide (ITO) electrodes and their H2-generating abili

112 ptoelectronic properties of colloidal indium tin oxide nanocrystals is reported.

113 of mesoporous, transparent conducting indium tin oxide nanoparticle (nanoITO) electrodes to prepare b

114 rs to enolate acceptors on conductive indium tin oxide surfaces.

115 he most common transparent conductor, indium tin oxide (ITO), with a material that gives comparable p

116 This control is achieved by embedding indium tin oxide (ITO) into these cavities.

117 Epitaxial indium tin oxide films have been grown on both LaAlO3 and yttri

118 ace area conductive metal oxide film--indium tin oxide or antimony tin oxide--coated with a thin oute

119 of PVDF nanowires-PDMS composite film/indium tin oxide (ITO) electrode/polarized PVDF film/ITO electr

120 e and limited resources of indium for indium tin oxide (ITO) materials currently applied in most of t

121 conductive transparent electrodes for indium tin oxide replacement, e.g. in light-emitting diodes, or

122 of their counterparts on rigid glass/indium tin oxide substrates, reaching a power conversion effici

123 r cells have a p-i-n structure (glass/indium tin oxide/NiO(x)/perovskite/ZnO/Al), in which the ZnO la

124 s indicate that electrolyte gating in indium tin oxide triggers a pure electronic process (electron d

125 10(6)-fold compared with an isolated indium tin oxide nanoparticle, with an effective third-order su

126 same Au nanoparticle (AuNP)-modified indium tin oxide (ITO) coated glass surfaces.

127 e (GOx) was immobilized on a modified indium tin oxide (ITO) coated polyethylene terephthalate (PET)

128 ical cell comprising an fcc3-modified indium tin oxide cathode linked to a cobalt phosphate-modified

129 -aminopropyl-triethoxysilane modified indium tin oxide electrode (ITO/APTES/GO/HSA) has been develope

130 Chemically modified indium tin oxide nanoparticle modified electrodes were used to

131 When anchored to nanoITO (indium tin oxide), the ruthenium chromophore-catalyst assembly

132 occus elongatus , on a nanostructured indium tin oxide (ITO) electrode and to covalently immobilize P

133 sembled on a polyethylene naphthalate-indium tin oxide flexible substrate with a PCE of 3.12% is demo

134 Monodisperse 11 nm indium tin oxide (ITO) nanocrystals (NCs) were synthesized by t

135 he conducted experiments with a 10 nm indium tin oxide film, having plasmonic resonance in the 1500 n

136 y, slides coated with a thin layer of indium tin oxide (ITO) are the standard substrate for protein i

137 ted by a 20-nm-thick metallic film of indium tin oxide (ITO), a plasmonic material serving as a low-c

138 The working electrode was composed of indium tin oxide (ITO); the quasi-reference and auxiliary elect

139 graphene is much higher than that of indium tin oxide films, especially at large incident angles.

140 ub-picosecond optical nonlinearity of indium tin oxide nanorod arrays (ITO-NRAs) following intraband,

141 ectrode based on transparent layer of indium tin oxide was electrochemically modified with a layer of

142 Thin films of indium tin oxide-the prototypical transparent electrode materia

143 d enzyme coated NPs were deposited on indium tin oxide (ITO) coated flexible polyethylene terephthala

144 Bi NPs were fabricated on indium tin oxide (ITO) surfaces from a bismuth trichloride solu

145 of naphthalenediimides were grown on indium tin oxide by ring-opening disulfide-exchange polymerizat

146 l shaped of Mn3O4-Cn nanocomposite on indium tin oxide substrate.

147 two electrodes and were fabricated on indium tin oxide-coated substrates (e.g., polyester) simply by

148 s) deposited electrophoretically onto indium tin oxide (ITO) coated glass electrode and have been uti

149 An optically transparent patterned indium tin oxide (ITO) three-electrode sensor integrated with a

150 es onto a gold-nanoparticle-patterned indium tin oxide electrode.

151 graphene electrodes has out-performed indium tin oxide in power conversion efficiency (PCE).

152 ference devices using polycrystalline indium tin oxide (ITO) electrodes.

153 supported Ru(bda) catalyst on porous indium tin oxide (ITO) electrode.

154 tion from an individual semiconductor indium tin oxide nanoparticle is significantly enhanced when co

155 iency solar cells, on semitransparent indium tin oxide (ITO) and titanium dioxide (TiO2) electrodes.

156 ent is demonstrated by various shaped indium tin oxide (ITO) patterns.

157 is more electrochemically inert than indium tin oxide (ITO) where ITO undergoes reduction-oxidation

158 We report that indium tin oxide can acquire an ultrafast and large intensity-d

159 ieve this first requires showing that indium tin oxide surfaces can be used for SMLM, then that these

160 hrome c directly immobilized onto the indium tin oxide (ITO) surface, we measured a reaction rate con

161 electrophoretically deposited on the indium tin oxide coated glass substrate at a low DC potential.T

162 near field localized at its gap; the indium tin oxide nanoparticle located at the plasmonic dimer ga

163 ode show superior efficiency to their indium tin oxide (ITO) counterparts because of improved photon

164 ssy Mode Resonances generated by thin indium tin oxide (ITO) films fabricated onto the planar region

165 A novel titanium/indium tin oxide annealed alloy is exploited as transparent ohm

166 considered a promising alternative to indium tin oxide as transparent conductors.

167 Alternatives to indium tin oxide have recently been reported and include conduc

168 ymeric films on optically transparent indium tin oxide (ITO) electrodes.

169 n external potential to a transparent indium tin oxide-coated electrode (the substrate), which enable

170 rast, P450 BM3 adsorbed on unmodified indium tin oxide electrodes revealed 36% activity by electrode

171 comparable to those fabricated using indium tin oxide.

172 d yield become close to devices using indium tin oxide.

173 Whereas indium tin oxide (ITO) is a well-known transparent conductive o

174 onductive, transparent amorphous zinc indium tin oxide (a-ZITO) electrodes.

175 as coupled to an optically absorptive indium-tin-oxide (ITO) substrate can generate >micrometre per s

176 electrophoretically deposited onto an indium-tin-oxide glass substrate and used for immobilization of

177 was studied at glassy carbon (GC) and indium-tin oxide (ITO) electrodes modified by gold nanoparticle

178 ctrode is shown to perform as well as indium-tin oxide glass.

179 For this purpose, we integrate indium-tin-oxide (ITO) as a tunable electro-optical material in

180 of single redox events on a modified indium-tin oxide (ITO) electrode.

181 ce > 70%) that are rivalling those of indium-tin oxide.

182 ymer (MIP-FU) films were deposited on indium-tin oxide (ITO) or Au film-coated glass slides, Pt disk

183 and disposable immunosensor based on indium-tin oxide (ITO) sheets modified with gold nanoparticles

184 rolactone (PCL) electrospun fibers on indium-tin-oxide (ITO) glass provide a sufficient surface to re

185 tabilized Au nanoparticles (NPs) onto indium-tin-oxide-coated glass (glass/ITO) electrodes as studied

186 d on chips coated with either gold or indium-tin oxide.

187 We present indium-tin-oxide-based photocurrent measurements that reveal a

188 tailor-made hierarchically structured indium-tin oxide electrode that gives rise to the excellent int

189 electrophoretically deposited on the indium-tin-oxide (ITO) substrate.

190 A transparent indium-tin-oxide (ITO) nanolens was designed to focus the incid

191 The HO-1 inhibitor, tin protoporphyrin, blocked MP4CO protection, consistent

192 te the power of this approach by introducing tin-doped indium oxide nanocrystals into niobium oxide g

193 biquitous transparent conducting material is tin-doped indium oxide (ITO), a wide-gap oxide whose con

194 'nanocrystal-in-glass' composites (that is, tin-doped indium oxide (ITO) nanocrystals embedded in Nb

195 h three nonsilyl substituents, tri-isopropyl tin in this case.

196 ster core of [Ge18Pd3] and six tri-isopropyl tin substituents.

197 The group-IV tin has been hypothesized to possess intriguing electron

198 can be used to continuously circulate liquid tin at temperatures of around 1,473-1,673 kelvin.

199 h to the first complex featuring a manganese-tin triple bond that takes advantage of the propensity o

200 ollow" ethylenediammonium and methylammonium tin iodide ({en}MASnI3) perovskite as absorbers.

201 stallization of the lead-free methylammonium tin triiodide (CH3NH3SnI3) perovskite films in a solutio

202 perovskite solid solutions of methylammonium tin iodide and its lead analogue (CH3NH3Sn(1-x)Pb(x)I3).

203 A novel disposable microfabricated tin-film electrochemical sensor was developed for the de

204 ive study of a series of lead-free and mixed tin and germanium halide perovskite materials.

205 0 kV, where Sn indicates the use of a 0.4-mm tin filter) and magnetic resonance (MR) imaging.

206 on state led to the unconventional monomeric tin(II) kappa(4) tetrametaphosphate [Sn(P4O12)](2-) (4,

207 rough effective-medium theory, linear muffin-tin orbital theory, and the d-band model, we rationalize

208 open and closed sites, respectively (namely, tin bound to three or four siloxy groups of the zeolite

209 nteraction between CO2(*-) and the nanoscale tin surface and subsequent kinetic activation toward pro

210 At these novel nanostructured tin catalysts, CO2 reduction occurs selectively to forma

211 All the new tin hydrides remain metallic over their predicted range

212 luding copper, manganese, magnesium, nickel, tin, niobium, light rare earth elements (LREEs; lanthanu

213 me change of a high-specific-capacity nickel-tin nanocomposite during operation as a Li-ion battery a

214 The nickel-tin anode is supported by an electrochemically inactive

215 The catalytic activity of tin-containing zeolites, such as Sn-Beta, is critically

216 We have found that the addition of tin nanoparticles to a silicon-based anode provides dram

217 We show that the addition of tin to palladium catalysts coupled with an appropriate h

218 Even a minor addition of tin, as small as approximately 2% by weight, results in

219 plots obtained after subsequent additions of tin in a Pt-containing solution, it is possible to quant

220 CR24 and HO-1 and systemic administration of tin-protoporphyrin-IX, an HO inhibitor, abolished these

221 eloped for determination of trace amounts of tin in canned beverage samples, which is widely used in

222 se and synthetic scope, the applicability of tin-promoted selective protections.

223 The model estimates the upper bound of tin, tungsten, tantalum, and gold use within ICT product

224 mass through heavy doping, as in the case of tin-doped indium oxide (ITO).

225 as focused attention on the supply chains of tin, tungsten, tantalum, and gold (3TG), specifically th

226 hway of producing sizable 2D crystallites of tin is based on deintercalation of bulk compounds with s

227 ][Tf2N] as ionic liquid for the detection of tin employing electrothermal atomic absorption spectrome

228 The procedure allowed the determination of tin with limits of detection and quantification of 3.4 a

229 However, the efficiency of tin-based perovskite solar cells is still low and they e

230 atory, is composed by 14 sensing elements of tin dioxide thin layers (doped with Cr and In, and undop

231 nsional structural and chemical evolution of tin anodes in sodium-ion batteries with in situ synchrot

232 The liquid-phase exfoliation of tin(II) sulfide to produce SnS nanosheets in N-methyl-2-

233 platinum uses the intermediate formation of tin(II) ions, taking place during the tin cathodic reduc

234 The importance of tin oxide (SnO(x)) to the efficiency of CO(2) reduction

235 d in experiments with compressed mixtures of tin and barium titanate nanoparticles of varying composi

236 re also obtained with compressed mixtures of tin and strontium titanate nanoparticles.

237 lled with great precision, the nucleation of tin in solder joints is currently left to chance.

238 method was applied for the quantification of tin in several food samples.

239 )Sn(104) has been the sole representative of tin clathrates with the type II structure.

240 a correlation between surface segregation of tin ions and the average activation of dopants is observ

241 It is suggested that segregation of tin near the surface facilitates compensation of the dop

242 A strong influence of surface segregation of tin on the line shape of the localized surface plasmon r

243 generates on the anodic stripping signal of tin acidic solutions: in appropriate conditions platinum

244 Dynamical stability and superconductivity of tin hydrides are systematically investigated.

245 he hydrogen donor, thus obviating the use of tin-based reagents.

246 Perovskites based on tin, which is slightly smaller than lead, show the oppos

247 se solid species deposit preferentially onto tin-doped indium oxide instead of carbon during electroc

248 ation of a series of low-dimensional organic tin bromide perovskites with 1D and 0D structures is rep

249 PE HTL material in low-cost high-performance tin-based perovskite solar cells.

250 The best-performing tin iodide perovskite cells employing the novel mixed-ca

251 ed on boron, silicon, germanium, phosphorus, tin, and metal di-chalcogenides.

252 Platinum-tin (Pt/Sn) binary nanoparticles are active electrocatal

253 , extrinsically doped p-type polycrystalline tin selenides.

254 The family of solution-processed tin-based perovskites is demonstrated as a new and super

255 he presence of different species in the same tin, although this is forbidden by EU law.

256 nsitizing a degenerate n-type semiconductor (tin-doped indium oxide; ITO) is reported.

257 tovoltaics, especially for the air-sensitive tin-based perovskite systems.

258 mass-independent fractionations for several tin-bearing crystals are calculated from (119)Sn spectra

259 structure, in which individual seesaw-shaped tin (II) bromide anions (SnBr4(2-) ) are co-crystallized

260 Silicon (Si), tin (Sn), and germanium (Ge) alloys have attracted resea

261 Silicon, tin, and graphite were successfully prelithiated with th

262 of materials, including aluminium, silicon, tin and so on.

263 The synthesis feasibility of silicon-tin nanocrystals by discharges in liquid nitrogen is stu

264 Slight tin-substitution for indium in CeRhIn5 shifts its antife

265 ntercalation of bulk compounds with suitable tin frameworks.

266 New metal incorporated iron sulfur tin sulfide chalcogels referred to as ternary chalcogels

267 Porous carbon nanofiber (CNF)-supported tin-antimony (SnSb) alloys are synthesized and applied a

268 Here we show an unusual phenomenon that tin (Sn) microparticles with both poor size distribution

269 riations in zircon Hf and U/Yb reaffirm that tin belt magmas contain greater crustal contributions th

270 The tin(II) hydride [Ar((i)Pr6)Sn(mu-H)]2(Ar((i)Pr6) = C6H3-

271 d that the increased conductivity allows the tin oxide conversion and alloying reactions to both be r

272 ion of tin(II) ions, taking place during the tin cathodic reduction, to reduce itself and to form mix

273 In the case of 2, on the other hand, the tin fragment is found above one of the triangular bases

274 employed as the additional Lewis base in the tin halide solution to form SnY2 -TMA complexes (Y = I(-

275 of an oxygen atom from H5PV2Mo10O40 into the tin-carbon bond of n-Bu4Sn through its activation by ele

276 composition and crystalline structure of the tin element played important roles in the CO2 generation

277 ndent on the successful incorporation of the tin metal center into the zeolite framework.

278 der joints to control the orientation of the tin nucleation event.

279 occurs at the quantum critical point of the tin-doped metal.

280 ilane-based interfacial layers (IFLs) on the tin-doped indium oxide (ITO) anodes of organic photovolt

281 rsors, we developed a structure in which the tin nanoparticles are segregated at the interface betwee

282 Among these, tin-containing zeolites have demonstrated superior catal

283 ane spontaneous polarization in atomic-thick tin telluride (SnTe), down to a 1-unit cell (UC) limit.

284 ((HO)2OPCH2)2bpy)(OH2)](2+) surface bound to tin-doped indium oxide mesoporous nanoparticle film elec

285 re adducts involving addition of fluoride to tin.

286 Unlike tin-based perovskite compounds CsSnI3 and CH3NH3SnI3, wh

287 In this work, we use tin oxide, SnO2, as a representative anode material to e

288 Th3/(+) We observed that HO inhibition using tin protoporphyrin IX (SnPP) decreased heme-iron recycli

289 set from the paired Cu-Au (copper) and Sn-W (tin) magmatic belts in Myanmar.

290 action time and the chemometric response was tin recovery.

291 In contrast, when tin (Sn) is added to CeO2 , the single-atom Pt catalyst

292 estigate the variants of this compound where tin is substituted by germanium or silicon and find that

293 e delta(18)O (5.2-5.5 per thousand), whereas tin belt zircons have low epsilonHf (-7 to -13) and heav

294 mation was between 60 and 75% complete while tin-oxygen bond cleavage was much less advanced, between

295 le bimolecular recombination associated with tin and the reduced trap density with SnF2 treatment, th

296 s, we further prepare carbon nanofibers with tin-doped indium oxide nanoparticles decorating the surf

297 articles or of core/shell nanoparticles with tin-doped In2O3 nanoparticle (nanoITO) cores and thin la

298 Samples with tin segregated near the surface show a symmetric line sh

299 Copper zinc tin sulfide (CZTS) is a promising material for harvestin

300 nd Zn-MHHD, an ultrathin film of copper zinc tin sulfide (CZTS) was deposited.