ライフサイエンスコーパス: argon

1 into each 1 mg of liposomes (70% Xe and 30% argon).

2 the RTube (pH measured after deaeration with argon).

3 r to the measured concentration of dissolved argon.

4 18-crown-6 in Et(2)O at -35 degrees C under argon.

5 and its ionization cross-section relative to argon.

6 lomethanes or carbon tetrafluoride in excess argon.

7 l monolayer experiments were conducted under argon.

8 ond in nitrogen and 4 x 10(-5) per second in argon.

9 o strongly inhibited in samples flushed with argon.

10 erences for plasma generated in nitrogen and argon.

11 ctroscopy using the method of "tagging" with argon.

12 of 18-crown-6 in Et2O at -35 degrees C under argon: [(18-crown-6)K][Cp'3Tb], {[(18-crown-6)K][Cp'3Tb]

13 Argon-36 is believed to have originated from explosive n

14 are: carbon dioxide (CO2), 0.960(+/-0.007); argon-40 ((40)Ar), 0.0193(+/-0.0001); nitrogen (N2), 0.0

15 totoxic levels of blue-green light (20 mJ of argon 488 nm) over 2 weeks.

16 , a breathing gas mixture containing 50 vol% argon/50 vol% oxygen (argon group) or 50 vol% nitrogen/5

17 e requirement for a dispersive component for argon addition, and helps to keep the sample on axis wit

18 e evaluate the neuroprotective properties of argon after experimental subarachnoid hemorrhage with mo

19 ation for Aronia melanocarpa fresh fruits in argon and air atmospheres were investigated.

20 uoromethyl)carbene were synthesized in solid argon and characterized by IR, UV-vis, and electron para

21 ction of hydrogen and larger species such as argon and cyclohexane.

22 beculoplasty, using either photocoagulative (argon and diode) or photodisruptive (frequency doubled N

23 We infer that carbon, helium, argon and highly incompatible heat-producing elements (s

24 for approximately 100% of the non-radiogenic argon and krypton and 80% of the xenon.

25 tors to study the phase behavior of adsorbed argon and krypton atoms as well as their coupling to the

26 ic generation in the solid and gas phases of argon and krypton.

27 OCO) have been studied by IR spectroscopy in argon and nitrogen matrices.

28 A technique based on cold argon and oxygen plasmas permits radiocarbon dates to be

29 formalin, neodymium/yttrium aluminum garnet, argon and potassium titanyl phosphate laser treatments,

30 in the same triplet states trapped in solid argon and provides evidence for four distinct CUO(Ar)(4-

31 ith single water molecules embedded in solid argon and switches its ground state from triplet to sing

32 HSMC method is applied to systems of liquid argon and the TIP3P model of water, and very good result

33 Sputter yield studies using argon and water beams on arginine and Irganox 1010 have

34 uraging in themselves, suggest that for both argon and water cluster beams, higher energy beams, e.g.

35 cular nitrogen, methane, molecular hydrogen, argon, and a host of stable carbon-nitrile compounds in

36 nd laser-ablated Zr atoms, isolated in solid argon, and investigated by means of infrared spectroscop

37 is more unfolded for the heavy gases (neon, argon, and nitrogen) but not the case for helium.

38 mixtures (PSMs) containing helium, hydrogen, argon, and oxygen in a balance gas of nitrogen.

39 Argon application after experimental subarachnoid hemorr

40 s may contribute to the beneficial effect of argon application after subarachnoid hemorrhage.

41 produce MPs according to the potency series: argon approximately nitrogen > helium.

42 sing acetylene (C2H2) as carbon source in an argon (Ar) and nitrogen (N2) atmosphere.

43 pecies generated in cell culture media by an argon (Ar) plasma jet.

44 C) requires accurate gas mixtures containing argon (Ar), helium (He), hydrogen (H(2)), and oxygen (O(

45 With concurrent measurements of argon (Ar), which has similar solubility properties as o

46 Through ultraviolet laser argon-argon dating of potassium feldspar cements contain

47 or for more than 37 weeks when stored under argon at -25 degrees C.

48 haracterized after a first heat treatment in argon at 1050 degrees C (Ar) and a second heat treatment

49 with subsequent trapping of the products in argon at 3 K.

50 bon was generated by heating the PFA-SWNT in argon at 600 degrees C, a process during which the PFA w

51 which is trapped in a triplet state in solid argon at 7 K, based on agreement between observed and re

52 plished by doping the flame's fuel flow with argon at a level to match that in the laboratory's air.

53 lyl, and 1-naphthyl azides were deposited in argon at low temperature in the presence and absence of

54 Argon, at a flow rate of 125 mL min(-1), was the best DB

55 Argon, at a flow rate of 60 mL min(-1), was the best DBD

56 onally simple reaction can be carried out in argon atmosphere as well as in air and under neutral rea

57 omers (n </= 4) during the reaction under an argon atmosphere at various predesigned temperatures (10

58 ibit clean, low-temperature decomposition in argon atmosphere that results in phase-pure perovskite f

59 ecomposition of heterometallic precursors in argon atmosphere was shown to yield phase-pure sodium-ra

60 ntrolled thermal decomposition of coal in an argon atmosphere, it is possible to determine the differ

61 es C, 900 degrees C and 1000 degrees C under argon atmosphere.

62 dard rich media (YPD and YPGal) under O 2 or argon atmospheres.

63 ic oxide using a single collision between an argon atom and a molecule of NO.

64 ere E is the beam energy and n the number of argon atoms in the cluster) and fall rapidly when E/n <

65 are obtained by first attaching weakly bound argon atoms to the clusters and then monitoring the phot

66 etic energy electronicallyexcited metastable argon atoms was studied in a linear trap-time-of-flight

67 Metastable argon atoms were generated using a glow discharge-type s

68 , which is limited by the temperature of the argon atoms, is unprecedented in this spectral region an

69 ling and cleaning it and feeding most of the argon back to the outer gas port of the torch.

70 rial endocardial lesion set using a flexible argon-based cryoablative device.

71 With the latest generation argon-based cryoprobes, the risk of long-term incontinen

72 Cryoablation using this flexible argon-based device for the treatment of AF during concom

73 We report our results using argon-based endocardial cryoablation for the treatment o

74 Ion yield enhancements relative to the argon beam on the order of 10 or more have been observed

75 be as high as 20, relative to 0.05 under an argon beam.

76 hance proton related ionization over against argon beams to a significant degree such that enhanced d

77 o 27 GeV in a high-ionization-potential gas (argon), boosting their initial 20.35 GeV energy by 130%.

78 oft surfaces consisted of either a submerged argon bubble or a thin polydimethylsiloxane (PDMS) layer

79 ramide analogs in monomolecular films at the argon-buffer interface.

80 re therapy, and charged-nuclei therapy (with argon, carbon, helium [alpha particles], neon, nitrogen,

81 ate that the introduction of hydrogen to the argon carrier gas dramatically improves the optical qual

82 tion, growth region, growth temperature, and argon carrier gas flow rate.

83 e-time" protocol, with and without plasma of argon cleaning treatment.

84 r cluster primary ion beams in comparison to argon cluster beams over a range of cluster sizes and en

85 iversal sputtering curve derived by Seah for argon cluster beams.

86 Whereas optimum ion yields under argon cluster bombardment occur in the region of E/n >/=

87 uality of the depth profiles, especially the argon cluster ion beam, as it is characterized by a grea

88 under NO dosing and with sample cooling) and argon cluster ion beams (using Ar1500(+) ions at 5 keV).

89 ndary ion mass spectrometer equipped with an argon cluster ion for sputtering and a bismuth liquid me

90 Argon cluster ion sources for sputtering and secondary i

91 he depth profiling of organic materials with argon cluster ion sputtering has recently become widely

92 ntial of organic depth profiling using novel argon cluster ions, Ar(500)(+) to Ar(1000)(+).

93 Argon cluster secondary ion mass spectrometry analyses o

94 In this work, we assess the performance of argon cluster sources in an interlaboratory study under

95 In accordance with a previous report, argon cluster sputtering is shown to provide effectively

96 ectrometry for analysis, three of them using argon cluster sputtering sources and one using a C(60)(+

97 We observe that, with argon cluster sputtering, the position of the marker lay

98 espectively, in the mass spectrum of charged argon clusters formed in a low-temperature free-jet expa

99 In the argon clusters investigated, nanoplasma is mainly formed

100 Further, on some samples, large argon clusters produce changes in the mass spectra indic

101 onding DI models constructed for the charged argon clusters provides compelling evidence that the nat

102 Large argon clusters show reduced damage accumulation compared

103 ll 4d (10) ground state, may likewise (as in argon clusters) be viewed primarily in terms of (conside

104 s employed energies of 2.5 and 5 keV for the argon clusters, and both the sputtering yields and depth

105 y therapy, thermal ablation, such as ionized argon coagulation (IAC), is now commonly used as adjunct

106 The argon concentration time-series was used to investigate

107 The argon concentration time-series were also used to estima

108 o estimate travel times by cross correlating argon concentrations in the groundwater with argon conce

109 argon concentrations in the groundwater with argon concentrations in the river.

110 Under argon condition, the response current increased linearly

111 Thereby, the total argon consumption could be reduced from 14 to 1.4 L min(

112 The argon contents reach a maximum that persists to pressure

113 molecular ions of alkaline earth metals and argon could be identified as spectral interferences in a

114 Plasma of argon could be used to disinfect implant abutments befor

115 major phases of the terrestrial planets, and argon diffusion in these phases is slow at upper-mantle

116 Argon does not freeze at temperatures normal for souther

117 With a background gas of oxygen or argon, electron transfer reactions yielding excess OH(-)

118 The argon electrospray interface is successfully installed o

119 designed to assist in the development of an argon electrospray sample introduction system for low-fl

120 lar hydrogen and regions of enhanced ionized argon emission.

121 eported after retinal detachment surgery and argon endolaser.

122 e spray of 5% (v/v) methanol-water in a pure argon environment is achieved, eliminating the aforement

123 nformer of K(+)(Tryp)(H(2)O), trapped by the argon evaporative cooling process, was identified.

124 produced by milling elemental Li and Z in an argon-filled jar.

125 Similar work with dilute Kr and Xe in argon finds small frequency shifts in new four-band prog

126 4 solution, stripped from the solution by an argon flow and detected.

127 Plasma parameters (radio frequency power and argon flow rates) were optimized.

128 ric nitrogen using a mixture of nitrogen and argon flowing over bulk beta-sodium azide or beta-sodium

129 We present a simulator (ARGON) for the DTWF process that scales up to hundreds o

130 lent fit for the experimental data of liquid argon, for a range of thermodynamic conditions, as well

131 mation pattern, induced by the adsorption of argon, for IRMOF-74-V.

132 Hydrogen, methane, carbon dioxide and argon gas adsorption isotherms are reported and the sele

133 d by subliming them into a stream of flowing argon gas and then passing them through an oven heated t

134 A systematic study of the suitability of argon gas cluster ion beams (Ar-GCIBs) of general compos

135 and increasing the amount of added oxygen to Argon gas increased the changes in the safranal and croc

136 er quantum simulations are preferred for the argon gas while lower values are promoted by experimenta

137 ) at 1.5 keV in a collision cell filled with argon gas, for confident identification of the detected

138 Tabletop argon gas-based cryoablation system with a double-freeze

139 replacing the oxygen dissolved in water with argon gas.

140 during the titrations (pH 6.5, stirred under argon gassing).

141 The analogous reactions in excess argon give two persistent photoreversible matrix configu

142 ation, the worse-seeing eye was treated with Argon green laser (10 to 15 laser spots; 200-mum spot si

143 nretinal photocoagulation (PRP) using either argon green laser (41 eyes treated before February 2007)

144 us injection of Rose Bengal dye, followed by argon green laser treatment of the vessels at the optic

145 Body weight was higher in the argon group over the entire observation period (p < 0.05

146 g good overall condition was observed in the argon group over the entire observation period.

147 al neurons in the hippocampal samples of the argon group was discovered 24 hours after subarachnoid h

148 ure containing 50 vol% argon/50 vol% oxygen (argon group) or 50 vol% nitrogen/50 vol% oxygen (control

149 se 1 in the hippocampus was increased in the argon group.

150 Argon has been investigated in cerebral, myocardial, and

151 urements require that 66% of the atmospheric argon has been lost to space.

152 we present constraints on the solubility of argon in aluminosilicate melt compositions up to 25 GPa

153 Argon in headspace gave significant oxidation also at 70

154 Samples of milk with air or argon in headspace were exposed to narrow wavelength ban

155 The argon includes primordial 36Ar, and the radiogenic isoto

156 ults, D s slightly decreases with increasing argon injecting pressure for San Juan coal.

157 Calculations of seasonal transport of argon into and out of southern high latitudes point to m

158 PS) was sputter deposited on silver using an argon ion beam in order to investigate these parameters

159 ry electrophoresis instrument fitted with an argon ion laser detector (488 nm) and a broad band emiss

160 d with 450- to 490-nm light or with a 488-nm argon ion laser line as a result of fluorescence resonan

161 rescent dye Syto 9 and excited with a 488-nm argon ion laser.

162 Argon ion-sputtering destroys the aged configuration, yi

163 e first generation system was composed of an argon-ion laser that excited fluorescent beads at 457 nm

164 e transformation, with free electrons and/or argon ions proposed to account for the remainder.

165 Based on larger-than-expected gradients in argon isotopes, Camacho et al. propose a new explanation

166 ike isotopic composition, heavy noble gases (argon, krypton and xenon) have an isotopic composition v

167 Argon laser and selective laser trabeculoplasty are safe

168 The exact mechanisms by which argon laser and selective laser trabeculoplasty lower in

169 cuss the differences between the traditional argon laser and the PASCAL.

170 s now being substituted for the conventional argon laser for PRP in many clinics.

171 fective than that performed with traditional argon laser in effecting lasting regression of retinal n

172 uding cataract extraction, paracentesis, and argon laser iridoplasty.

173 Three sizes of argon laser lesions designed to damage the outer retina

174 arboxyfluorescein (6-CF) dye and cut with an argon laser microbeam (lambda = 488 nm).

175 ation and reduction of neovascularization by argon laser pan-retinal photocoagulation successfully ma

176 photography) and therapeutic interventions (argon laser photocoagulation, photodynamic therapy, intr

177 Anesthetized cats underwent retinal argon laser photocoagulation.

178 Patients treated with the PASCAL and argon laser received a similar number of spots (1438 vs

179 tungsten-halogen (QTH), plasma-arc (PAC), or argon laser sources in monolayer culture.

180 infants who had previously undergone retinal argon laser therapy of ROP.

181 ch of 12 cynomolgus monkeys was treated with argon laser to the anterior chamber angle to induce elev

182 3.14, P < 0.01, 95% CI, 1.91-5.17) and past argon laser trabeculoplasty (HR 1.81, P < 0.01, 95% CI,

183 escribe the proposed mechanisms of action of argon laser trabeculoplasty and selective laser trabecul

184 t interaction for the treatment sequences of argon laser trabeculoplasty and trabeculectomy, and that

185 mized patients with early glaucoma either to argon laser trabeculoplasty plus betaxolol (n = 129) or

186 trabeculoplasty may be a better option than argon laser trabeculoplasty.

187 Argon laser treatment of the anterior chamber angle was

188 Argon laser treatment of the anterior chamber angle was

189 Argon laser treatment with selected use of anti-VEGF the

190 At the end of the lens-rearing period, an argon laser was used to ablate the fovea in one eye of e

191 An argon laser with a beam diameter of 100 mum, exposure du

192 docyanine green angiography and treated with argon laser with and without anti-vascular endothelial g

193 er photocoagulation in C57BL/6 mice using an argon laser, and the animals received rCD59-APT542 via i

194 xtrafoveal involvement and were treated with argon laser.

195 tion in C57BL/6 and Cd59a(-/-) mice using an argon laser.

196 ore comfortable profile when compared to the argon laser.

197 /YFP) entails suboptimal donor excitation by Argon lasers, thereby hindering FRET imaging on many con

198 ents followed by cryogenic trapping in solid argon led to the formation of "late" stable oxidation pr

199 H/D kinetic isotope effects in nitrogen and argon matrices ( approximately 5 and >100, respectively)

200 ic saccharin was isolated in low-temperature argon matrices and its photochemistry was characterized

201 n comparison, the irradiation of azides 1 in argon matrices at 14 K lead to the formation of the corr

202 Monomers of 1 were isolated in argon matrices at 15 K and characterized spectroscopical

203 ition of both triazides with 254 nm light in argon matrices at 5 K occurred selectively to subsequent

204 The carbene is investigated in argon matrices by IR, UV-vis, and X-band EPR spectroscop

205 QM/MM calculations in simulated argon matrices reveal that an OH...pi complex is unstabl

206 In water-doped argon matrices, an OH...O complex between 1 and water is

207 The two compounds were isolated in an argon matrix (15 K) and the matrix was subjected to in s

208 this process, was matrix-isolated in a solid argon matrix and characterized by UV-vis as well as IR s

209 s and cis-to-trans conversions of DOCO in an argon matrix and HOCO and DOCO in a nitrogen matrix, whi

210 alloys followed by atom reactions in a solid argon matrix and trapping at 8 K gives weak infrared abs

211 ontrast, FLP 7 is carbonylated in a CO-doped argon matrix at 25 K to selectively form a borane carbon

212 lcarbamoyl azide has been investigated in an argon matrix at cryogenic temperatures.

213 cetone and deuterated acetone isolated in an argon matrix have been recorded for the understanding of

214 to form biradical 6, which was identified by argon matrix isolation, isotope labeling, and molecular

215 Nitrenes 2 were further characterized with argon matrix isolation, isotope labeling, and molecular

216 of 5-methyltetrazole isolated in a cryogenic argon matrix leads to formation of methyl nitrile imine

217 in different singlet-triplet spin states or argon matrix packing configurations.

218 n matrix (by 2 orders of magnitude versus an argon matrix) is much smaller than that on cis-HOCO (est

219 In an argon matrix, only the lower-energy conformer trans-HOCO

220 triplet 2-formylphenylnitrene isolated in an argon matrix.

221 Photolysis of 1 in argon matrixes at 14 K produced ketene imine 7, which pr

222 Similarly, photolysis of 1b in cryogenic argon matrixes results in ylide 8.

223 Likewise, irradiation of 1a in cryogenic argon matrixes through a Pyrex filter results in the for

224 copper, silver, and gold with H(2) in excess argon, neon, and pure hydrogen during condensation at 3.

225 containing ELIP (NO-ELIP) or a mixture of NO/argon (NO/Ar-ELIP) was studied.

226 account for the xenon deficiency relative to argon observed in terrestrial and Martian atmospheres.

227 Fractionation of argon occurs as a result of loss of gas to space by pick

228 ent drift gases (helium, neon, nitrogen, and argon) on the transport of multiply charged ions of the

229 m ferricyanide as an electron mediator under argon or atmospheric conditions.

230 d by photolysis of 1-azulenyldiazomethane in argon or neon matrices at 3-10 K.

231 by colliding it into inert gas atoms such as argon or xenon.

232 craft measured an enhancement of atmospheric argon over southern high latitudes during autumn followe

233 Under argon, over half of substrate alcohols, PhCH(OH)R, are c

234 The diffusion profiles of carbon dioxide, argon, oxygen, and methane were also investigated.

235 g the concentration time-series of dissolved argon, oxygen, carbon dioxide, and temperature during lo

236 es of dielectric breakdown strength (helium, argon, oxygen, carbon dioxide, nitrogen, and sulfur hexa

237 , D s almost didn't change after methane and argon penetrations for all these samples except Marcellu

238 Successful treatment was achieved with argon plasma coagulation (APC) applied circumferentially

239 odysplasia and GAVE hemorrhage by endoscopic argon plasma coagulation (APC).

240 Argon plasma coagulation is effective as an adjunct to p

241 Argon plasma coagulation is helpful in restoring continu

242 ased on currently available data and trends, argon plasma coagulation is the favored treatment for bl

243 Argon plasma coagulation presents an effective, efficien

244 ith neodymium:yttrium-aluminum-garnet laser, argon plasma coagulation, electrocautery, nonthermal abl

245 modalities modeled included radiofrequency, argon plasma coagulation, multipolar electrocoagulation,

246 tanyl phosphate laser treatments, as well as argon plasma coagulation.

247 more industrially viable alternative to the argon plasma desulfurization process is needed.

248 ous silicon nanowell arrays were prepared by argon plasma etching through an alumina mask.

249 lane of 2H-molybdenum disulfide (MoS2) using argon plasma exposure exhibited higher intrinsic activit

250 Particle-in-cell simulations show that the argon plasma is sustaining very high electric fields, of

251 pure oxygen (O2) in an atmospheric pressure argon plasma jet (kINPen) will change type and concentra

252 METHODOLOGY: Argon plasma treatment was investigated as a mechanism f

253 temperatures attained by employing moderate argon pressure (autoclave) over the reaction mixture led

254 olecules, solid aluminum arsenide, and solid argon provide numerical illustrations.

255 eve comparable results with the conventional argon PRP in the treatment of patients with diabetic ret

256 es are prepared via melt-quench method in an argon-purged atmosphere.

257 on an iridium strip resistance heater in an argon-purged chamber.

258 In the "argon-purged" solution, the terminal nu(CO) band on Au(1

259 tor-metal transition depending on the iodine/argon ratio in the sputtering gas.

260 xygen and its displacement when flushed with argon requires that reliable determinations of red blood

261 Postconditioning with argon resulted in a reduction of risk with respect to pr

262 ons of the thioether-containing adducts with argon results in conversion to bis(mu-oxo)dicopper(III)

263 oceanic lithosphere consisting of relatively argon-rich olivine and orthopyroxene.

264 Photolysis of 3 in argon-saturated 2-propanol led to formation of 5 via int

265 Laser flash photolysis of 1a in argon-saturated acetonitrile (lambda = 308 nm) results i

266 ysis of 3-methyl-2-phenyl-2H-azirine (1a) in argon-saturated acetonitrile does not yield any new prod

267 The rate constant for forming 4 in argon-saturated acetonitrile is 1.6 x 10(7) s(-1).

268 Laser flash photolysis of 2 in argon-saturated acetonitrile likewise results in the for

269 Similarly, photolysis of 2 in argon-saturated acetonitrile results in 1 and a trace am

270 Laser flash photolysis of azide 1 in argon-saturated acetonitrile shows formation of vinylnit

271 Photolysis of 1 in argon-saturated acetonitrile yields 2, whereas in oxygen

272 Photolysis of 1a yields 4a in argon-saturated methanol, whereas 1b is photostable.

273 built-in acetophenone triplet sensitizer, in argon-saturated toluene results in azirine 2, whereas ir

274 by the addition of NO, and was inhibited by argon saturation, indicating an indirect role for cytoch

275 Under the conditions of argon saturation, the NO consumption rate was not enhanc

276 ith this simple magmatic degassing scenario--argon seems to be compatible in the major phases of the

277 ch the neuroprotective noble gases xenon and argon should be administered, during or after ischemia,

278 A distinct drop in argon solubility observed over a narrow pressure range c

279 h increased odds (OR = 7.24, P = .0125), and argon suture lysis procedure was associated with decreas

280 ethod was first tested using a simple liquid argon system, and then applied to a neat dioleoylphospha

281 Using the argon tagging method, we show how variations in temperat

282 The argon-tagging technique was used to lower the internal e

283 milling atmospheres such as air, nitrogen or argon the same milling treatment produces nanosized part

284 ariety of environments, ranging from gaseous argon to liquid water containing a selection of hole sca

285 aser-ablated U atoms react with CO in excess argon to produce CUO, which is trapped in a triplet stat

286 lternative to magmatism is needed to release argon to the atmosphere, with one possibility being hydr

287 ngle-photon spectroscopy signals for both an argon transition at 82 nanometres and a neon transition

288 The absolute frequency of the argon transition has been determined by direct frequency

289 otocol by steaming) or test group (plasma of argon treatment).

290 dynamic conditions, as well as for saturated argon vapour.

291 Parameters such as carrier gas flow rate (argon), volume of oxidizing and potassium persulphate so

292 infrared spectrum of TSMT isolated in solid argon was fully assigned on the basis of the spectrum ca

293 Meta-analysis for argon was only possible in cerebral ischemia reperfusion

294 Noble gases other than argon were not detected.

295 This system is capable of collecting all argon which was initially supplied to the torch, cooling

296 or (ii) flushing the anaerobic culture with argon (which should purge it of nitric oxide) before it

297 rticular harmonic when a window resonance in argon, which is off-resonant in the field-free case, is

298 rements of isotopes of nitrogen, carbon, and argon, which reveal interesting clues about the evolutio

299 curate isotope analysis of organics, LIBS in argon with relatively short integration times (<10 mus)

300 the freshly collected HABs by calcination in argon without any additional purification process, deliv