ライフサイエンスコーパス: vapor

1 tation)) that depends on the source of water vapor.

2 r provides mobile ions in acetonitrile (ACN) vapor.

3 extensive degassing of an isotopically light vapor.

4 indoor NO gas, even in the absence of water vapor.

5 t self-administered nicotine but not vehicle vapor.

6 end a liquid droplet above a film of its own vapor.

7 ntributes the majority of BBSOA from emitted vapors.

8 geometry and responds reversibly to chemical vapors.

9 th CH(4) (60-63%), CO(2) (34-38%), and H(2)O vapor (0.8-1%), trace concentration levels of H(2)S were

10 results in 1-step conversion of wet ethanol vapor (40 wt% in water) to hydrocarbons and water over a

11 ensile muscles driven electrothermally or by vapor absorption.

12 Gradients in the concentration of water vapor across the root system were as small as 10(-4).mM.

13 r irradiance provides energy to desorb water vapor adsorbed to desiccants and determines maximum AWC

14 Vegetation and atmospheric water vapor also had a profound influence on the LST changes,

15 le performance as high affinity material for vapor analyte sensing.

16 Although KO(2) reacts with water vapor and CO(2) to form KHCO(3) , it is highly stable in

17 actively sensed, clarifying the role of leaf vapor and energy transport in humidity and temperature r

18 ngmuir constant (k(L)) > 0.1 to adsorb water vapor and meet these maximum potentials.

19 of the PGEs has been attributed to condensed vapor and melt from an extraterrestrial impactor or to v

20 e esters (OPEs) were measured in atmospheric vapor and particle samples collected at six sites in the

21 rom the purely diffusive transport of liquid vapor and that the contact line is a pinned circle.

22 n film of the COF responded quickly to water vapor and was stable for months.

23 gh-purity and high-concentration formic acid vapors and solutions.

24 nced the thickness and permeability to water vapor, and made the films more hydrophilic.

25 iest quarter, annual mean temperature, water vapor, and precipitation during the coldest quarter.

26 pable of measuring water activity in liquid, vapor, and semisolid (e.g., hydrogels, cheese) phases.

27 can detect limonene, undecanal, and geraniol vapors, and differentiate between their smells utilizing

28 quench depth and explains the use of solvent vapor annealing rather than thermal annealing.

29 By solvent vapor annealing, a recrystallization and reorientation o

30 ed by a combination of Sb-flux method and Mg-vapor annealing, is reported.

31 hrough combined solvent additive and solvent vapor annealing, which mainly work on ZnP-TBO and 6TIC,

32 hat surfaces exposed to side-stream cannabis vapor are positive for THC at quantifiable levels.

33 as been assumed that the blood and the water vapor are the only sources of water to maintain water ba

34 other in response to shear force and solvent vapors, are presented and their X-ray structure is deter

35 ine their chemical activity, using saturated vapor as the analytical standard and thermodynamic refer

36 The reversible capture of water vapor at low humidity can enable transformative applicat

37 aracterized by measuring acetone and ethanol vapors at their characteristic C-H absorption from lambd

38 f MeHg and InHg with gas chromatography-cold vapor atomic fluorescence spectrometry (GC-CVAFS).

39 mic fluorescence spectrometry and Hg by cold vapor atomic fluorescence spectrometry after ultrasound-

40 d and dense morphology (E-SEM), higher water vapor barrier, better mechanical features (strength, ela

41 : After inhalation of a single puff of E-cig vapor, brain nicotine concentration rose quickly (mean T

42 Results show that the increase in water vapor can be largely attributed to human activities.

43 olecules, simultaneously realizing efficient vapor capturing, in situ water liquefaction, high-densit

44 Results: A single puff of E-cig vapor caused the nicotine concentration in the brain to

45 gnetically induced transparency in an atomic vapor cell with controllable nonlinearity.

46 m enhancing the functionality of traditional vapor cells.

47 frigerants in cooling equipment based on the vapor-compression cycle has triggered a major effort to

48 Here, we review the basics of the vapor-compression cycle together with the safety, enviro

49 of a solid are possible alternatives to the vapor-compression fridges found in homes.

50 hat completely differs from the conventional vapor-compression refrigeration.

51 corrections to the shape of the droplet and vapor concentration distribution provides estimates that

52 eometry and the zeroth-order distribution of vapor concentration, we obtain the leading-order contrib

53 rospinning jet; thus, on the condition where vapor condensation does occur, morphological features wi

54 olvent vapour could prevent or disrupt water vapor condensation onto the electrospinning jet; thus, o

55 tes would attain chemical equilibrium during vapor condensation.

56 , in terms of the ambient pressure and water vapor content.

57 energy and to achieve optical depths in warm vapors, corresponding to a ~16 times increase in vapor p

58 our statistical understanding of the liquid-vapor critical point.

59 ared with CAN(CBD) or VEH, and the number of vapor deliveries positively correlated with plasma THC c

60 obust and repeatable control over the atomic vapor density and over the associated optical depth.

61 We use large area chemical vapor deposited (CVD) graphene and MoS(2), enabling larg

62 otoconductivity signal is higher in chemical-vapor deposited (CVD) samples than exfoliated monolayers

63 Waals heterojunctions consisting of chemical vapor deposited monolayer molybdenum disulfide and solut

64 ate the effect of light on the properties of vapor-deposited a-Se glasses at a range of substrate tem

65 ring of different levels of smectic order in vapor-deposited glasses to suit various applications.

66 The predoping of N by chemical vapor deposition (CVD) dramatically increases the Ni dop

67 Chemical vapor deposition (CVD) has become a promising approach f

68 area TMDs on graphene substrates by chemical vapor deposition (CVD) is limited by slow lateral growth

69 structures form during Ni-catalyzed chemical vapor deposition (CVD) of ammonia borane.

70 Here, we report a facile chemical vapor deposition (CVD) strategy to synthesize the promis

71 Here, we report high-yield thermal chemical vapor deposition (CVD) synthesis of CNTs catalyzed by re

72 high temperature (HPHT) growth and chemical vapor deposition (CVD), how each is allowing ever more p

73 Chemical vapor deposition (CVD)-grown classical transition metal

74 article, the technique of initiated chemical vapor deposition (iCVD) is evaluated for electret applic

75 the use of few-layer metal organic chemical vapor deposition (MOCVD) grown BN as a two-dimensional b

76 Oxidative chemical vapor deposition (oCVD) of conductive polymers offers a

77 tages of two large-area techniques: chemical vapor deposition and inkjet-printing.

78 Here we present a chemical vapor deposition approach to TLG growth that yields grea

79 hods using mechanical agitation and chemical vapor deposition are adopted.

80 ity of large-area graphene grown by chemical vapor deposition are often limited by the presence of wr

81 ture based on multiple intercalated chemical vapor deposition graphene monolayers distributed in an o

82 nt of the generated hot carriers on chemical vapor deposition grown large area nanopatterned monolaye

83 In this work, chemical vapor deposition growth of highly crystalline few-layer

84 introduced elemental silicon during chemical vapor deposition growth of nonlayered molybdenum nitride

85 atoms into MoS(2) monolayers in the chemical vapor deposition growth.

86 cessible through liquid quenching, aging, or vapor deposition in the dark, indicating the formation o

87 ince its successful development via chemical vapor deposition in the past decade.

88 Chemical vapor deposition is one of the most promising approaches

89 lms with Re atoms via metal-organic chemical vapor deposition is reported.

90 iophene) (PEDOT) grown by oxidative chemical vapor deposition is used to fabricate transparent and co

91 A chemical vapor deposition method is developed for thickness-contr

92 synthesis of novel materials by the chemical vapor deposition method.

93 Most chemical vapor deposition methods for transition metal dichalcoge

94 -organic framework crystals through chemical vapor deposition of a dimolybdenum paddlewheel precursor

95 ystal-like order can be produced by physical vapor deposition of a molecule without any equilibrium l

96 carbon nanopipets (CNP) prepared by chemical vapor deposition of carbon into prepulled quartz capilla

97 pecifically, a pulsed metal-organic chemical vapor deposition process is developed, where periodic in

98 Besides annealing, we developed a chemical vapor deposition process to use Cu NPs as catalytic subs

99 es are synthesized using a one-step chemical vapor deposition process with rapid cooling.

100 that was based on BDPM-But and fabricated by vapor deposition provided a maximum electron mobility of

101 polymeric carbon nitride (PCN) by a chemical vapor deposition strategy.

102 s via a substrate-buffer-controlled chemical vapor deposition strategy.

103 ized in a Microwave Plasma Assisted Chemical Vapor Deposition System.

104 combined with the microwave-plasma chemical vapor deposition technique to explore metastable synthes

105 of micrometers are synthesized by a chemical vapor deposition technique.

106 rdness (up to 37 GPa) B(50)C(2) via chemical vapor deposition was achieved.

107 itaxy, atomic layer deposition, and chemical vapor deposition, along with their challenges, are also

108 of aluminum during ultrahigh vacuum physical vapor deposition, dense arrays of particles are created

109 e surface, resulting in lower density during vapor deposition, it also acts to form more networked st

110 Gas-phase methods, including chemical vapor deposition, show broader promise for the preparati

111 in producing stable glasses during physical vapor deposition.

112 be block copolymer lithography, and chemical vapor deposition.

113 lms were grown via aerosol assisted chemical vapor deposition.

114 Recent experimental chemical vapor depositions of silicon at extreme pressures of ~ 5

115 ep in understanding how side-stream cannabis vapor deposits in the environment and potentially result

116 porosity is associated with deep and narrow vapor depressions called keyholes, which occur under hig

117 rode does not, as it is covered with a water-vapor diffusion barrier ~8 nm of Al(2)O(3).

118 ositive reinforcing effects and low nicotine vapor discrimination.

119 Due to enhanced areas for vapor dissipation, the PPy origami improves the water ev

120 certain VOCs and prevent them from entering vapor emissions.

121 the IV cycle of the junction (+/-2 V) in ACN vapor, enhancing the reversible charge storage by a fact

122 difference testing can provide insight into vapor entry locations and indoor source contributions.

123 ic conditions are (1) the use of a miniature vapor-equilibration vessel (the "saturator") to minimize

124 rats exposed to chronic intermittent ethanol vapor (ethanol-dependent) displayed a significant increa

125 tinct responses to the four tested alcoholic vapors (ethanol, methanol, propanol, and isopropanol).

126 e effects of adolescent intermittent ethanol vapor exposure (AIE) on negative affect during acute and

127 ENDS-induced lipid deposition, chronic ENDS vapor exposure downregulated innate immunity against vir

128 hol dependence (chronic intermittent alcohol vapor exposure), ex vivo slice electrophysiology and ISH

129 membrane electrodialysis (BPMED) cell and a vapor-fed CO(2) reduction (CO(2)R) cell to capture and c

130 The direct coupled, vapor-fed CO(2)R cell yields a total Faradaic efficiency

131 certainties in polar regions while the water vapor feedback spread explains uncertainties elsewhere.

132 inter-model spreads of ice-albedo and water vapor feedbacks, and better understanding the spatial co

133 rnal flow reveals strong flow separation and vapor-filled cavities (cavitation), the degree of which

134 The insulating vapor film can be highly detrimental in metallurgical qu

135 This physical insight into vapor film dynamics allows us to derive an ab initio, ma

136 on a liquid-nitrogen pool and levitate on a vapor film generated by evaporation of the bath.

137 Here, we investigate the vapor film instability for small length scales that ulti

138 served (stable) symmetry breaking within the vapor film that supports the drop.

139 vaporation from the hot side, nonequilibrium vapor flow with a Knudsen number of about 0.02, and cond

140 pping and designed a graph-based classifier, VAPOR, for selecting mapping references, assembly valida

141 um of short-lived ROS and H(2)O(2)) than the vapor fraction.

142 by the incorporation of a >30 per mille HCl vapor from a highly evolved LMO.

143 An increase in water vapor from near zero to 70% relative humidity (RH) at hi

144 By modifying the desolvation gas with acid vapor from propionic acid (PA) and isopropanol (IPA), th

145 and optimize the best condition of chemical vapor generation (CVG) and simultaneous determination of

146 Herein, we developed a photochemical vapor generation (PVG) method for the green and direct s

147 Efficient photochemical vapor generation (PVG) of tungsten has been achieved for

148 However, high energy consumption of vapor generation fundamentally restricts practicality of

149 Solar vapor generation has presented great potential for waste

150 Additionally, the vapor generator was connected to the SMS unit, which was

151 evaluated together with a hazardous chemical vapor generator.

152 hat volitional exposure to THC-rich cannabis vapor has bona fide reinforcing properties and collectiv

153 Our data indicate that THC-rich cannabis vapor has reinforcing properties that support stable rat

154 VAPOR has the potential to improve the robustness of bio

155 evaluated the efficacy of hydrogen peroxide vapor (HPV) to inactivate MS2 and Phi6 bacteriophages, t

156 ighlights key mechanisms through which water vapor (i) adsorbs and (ii) condenses at mineral surfaces

157 microsystem can selectively detect vanillin vapor in a concentration range from 2.7 ppt to 0.3 ppm,

158 prepare materials that can convert the water vapor in the air to collectible liquid water is still mo

159 Moreover, we identify vapor-induced single crystal transitions that are revers

160 Exposure to hydrazine vapors induces structural and chemical changes that mani

161 M) mass concentration: isotope dilution cold-vapor inductively coupled plasma mass spectrometry (ID-C

162 The dynamics and structure of the liquid and vapor interface has remained elusive for decades due to

163 ysicochemical processes driven at the liquid-vapor interface of fermented molasses, generated by the

164 non-equilibrium thermodynamics of the liquid-vapor interface to benefit future engineering designs in

165 he real-time dynamic structure of the liquid-vapor interface was imaged and videoed by TEM on the sam

166 ong-debated theoretical models of the liquid-vapor interface, and enhancing our knowledge in understa

167 vapor mass and the evaporation at the liquid-vapor interface.

168 g is a building-specific diagnostic tool for vapor intrusion (VI) pathway assessment which offers adv

169 the interphase layer between bulk phase and vapor is much smaller than the cohesive energy in the co

170 ions show that the catalytic effect of water vapor is not observable at 200-400 K.

171 Low concentration hydrogen peroxide vapor (LCHP; 25 ppm) was effective against both phages o

172 of thermodynamic capillary condensation of a vapor-liquid phase between parallel plates, suggesting t

173 mposite is obtained through a combination of vapor-liquid-solid (VLS) and two-phase epitaxy growth me

174 In this study, a self-capping vapor-liquid-solid reaction is proposed to fabricate lar

175 tionation at reduced nebular environment and vapor loss of lighter Si isotopes during planetary volat

176 id-vapor surface tension-driven transport of vapor mass and the evaporation at the liquid-vapor inter

177 e projections suggest that atmospheric water vapor may increase faster (slower) than that revealed by

178 Dynamic vapor microextraction (DVME) is a new method that enable

179 The inclusion of the water vapor modifier to the FAIMS methodology is made more rob

180 is presented herein with the use of a water vapor modifier.

181 improved peak capacity with the addition of vapor modifiers to the carrier gas.

182 he Fano resonance mode in the PCS due to the vapor molecule adsorption and desorption induced changes

183 lel confirmed the direct binding between the vapor molecules and the peptide-SWCNTs.

184 in southeast Louisiana using passive organic vapor monitors and gas chromatography/mass spectrometry

185 NIR light adsorption heats the HGN, inducing vapor nanobubbles that rupture the liposome, releasing c

186 By exposing headspace vapor of the selected reagents to corona discharge, solv

187 nor hardware modification is needed to allow vapors of a variety of liquid reagents to be leaked into

188 We demonstrate sensing of 50-1000 ppm of vapors of ammonia and hydrogen chloride, components comm

189 nstructed and their performance for removing vapors of toluene and methanol was assessed.

190 based materials and devices to capture water vapor off the electrical grid have been reported, all of

191 es of the possible catalytic effect of water vapor on CH(3) OH + OH reaction, we report calculations

192 ets formed by dropwise condensation of water vapor on low-temperature substrates.

193 relative contribution of various fractions (vapors, organics, metals, and metal oxides) have not bee

194 The elongation at break and the water vapor permeability (WVP) values of the films were found

195 physical properties such as oxygen and water vapor permeability (WVP), swelling, water solubility and

196 AP did not affect the water vapor permeability and tensile strength of the OSA-based

197 ile strength, contact angle, porosity, water vapor permeability and water uptake ratio of CA/Gel nano

198 cal and barrier properties such as low water vapor permeability, solubility and water holding capacit

199 ngation at break, moisture content and water vapor permeability.

200 In general, the loss rates of vapor phase chlorinated pesticides have slowed by about

201 copy is further used to correlate the global vapor phase conditions and the boundary defect types.

202 lk liquid and the solid substrate across the vapor phase drives film collapse.

203 centration of carbon in GaN grown by hydride vapor phase epitaxy (HVPE).

204 exceeding 300 um h(-1) using dynamic hydride vapor phase epitaxy.

205 n contrast, free-OH groups sticking into the vapor phase exhibit substantially slower vibrational dyn

206 We use a controllable vapor phase synthesis method using MoSe(2) powder as the

207 rine monomer as the principal species in the vapor phase, with a significant enantiomeric enrichment

208 The vapor-phase analyte is produced through a reactive olfac

209 d easily accessible compared to conventional vapor-phase deposition, and the particle size and struct

210 xamined over Ga/H-MFI catalysts prepared via vapor-phase exchange of H-MFI with GaCl(3).

211 Devices are readily fabricated from single vapor-phase grown crystals and exhibit reversible 8-fold

212 verview of recent developments in controlled vapor-phase growth of 2D transition metal dichalcogenide

213 sites on metal-organic frameworks (MOFs) by vapor-phase infiltration (VPI) was developed.

214 Using the enantiomeric excess (ee %) of the vapor-phase monomer as the input, the model output match

215 , we significantly expand upon the number of vapor-phase postmodification processes reported to date

216 This vapor-phase single Fe atom transport mechanism is verifi

217 ns (benzene, cyclohexane) both in liquid and vapor phases was thoroughly investigated for all compoun

218 d changes in the canopy conductance to water vapor, photosynthetic photon flux density, vapor pressur

219 new evidence of electric charging during the vapor plume cloud processes.

220 ood agreement for the more volatile SVOCs of vapor pressure (VP) exceeding 10(-5) Pa and correspondin

221 cit, the impact of temperature on saturation vapor pressure and access to groundwater muted the respo

222 re correlated to their Henry's Law constant, vapor pressure and water solubility.

223 elevation, (ii) temperature variability and vapor pressure are the strongest drivers of geographic s

224 eaves, e (i) approached 0.6 times saturation vapor pressure before the precipitous decline in transpi

225 Vapor pressure deficit (VPD) and air temperature were ma

226 ldwide, resulting in an exponential climb in vapor pressure deficit (VPD).

227 tendencies of T/ET increasing with dryness (vapor pressure deficit and days since rain) and with lea

228 .4 degrees C, coupled with a 1.0 kPa drop in vapor pressure deficit having a 9-minute lag following t

229 negative coupling between soil moisture and vapor pressure deficit occurs globally, indicating high

230 isture status through their influence on the vapor pressure deficit of the atmospheric boundary layer

231 odels that represent the response of g(s) to vapor pressure deficit performed better than correspondi

232 soil moisture) and atmospheric aridity (high vapor pressure deficit) can be disastrous for natural an

233 r vapor, photosynthetic photon flux density, vapor pressure deficit, and air temperature.

234 se to interannual variations in temperature, vapor pressure deficit, and precipitation, and responses

235 tion driven by T(air) , light intensity, and vapor pressure deficit, and T(leaf) was strongly linearl

236 n dioxide concentrations, soil moisture, and vapor pressure deficit, the impact of temperature on sat

237 measured the stomatal response to changes in vapor pressure difference (VPD) in two natural forms of

238 rs, corresponding to a ~16 times increase in vapor pressure in less than 20 ms, with possible reload

239 were shown to be sufficient for high-quality vapor pressure measurements at 364 K.

240 The performance of DVME was validated with vapor pressure measurements of n-eicosane (C(20)H(42)) a

241 on (DVME) is a new method that enables rapid vapor pressure measurements on large molecules with stat

242 We use vapor pressure measurements to identify aqueous liquid c

243 2 mg/L at 20 degrees C) and highly volatile (vapor pressure of 6.7 mPa at 20 degrees C); these physic

244 valley are then evaporated due to the lower vapor pressure of ice compared with water, resulting in

245 ) as a model system, high boiling point (low vapor pressure) solvents give rise to highly robust and

246 exchange were used to estimate intercellular vapor pressure, e (i) In wild-type leaves, there was no

247 table electrical conductivity and negligible vapor pressure.

248 rounding pressure drops below the saturation vapor pressure.

249 trongly affected by PAR, air temperature and vapor-pressure deficit.

250 gulation by CO(2) and, as hypothesized here, vapor-pressure deficit.

251 tanol-air partition coefficients (K(OA)) and vapor pressures (P(L)) of the OPEs were also measured as

252 Airborne concentrations of SVOCs with vapor pressures corresponding to C25 to C31 alkanes corr

253 Airborne concentrations of SVOCs with vapor pressures in the range of C13 to C23 alkanes were

254 state-of-the-art measurement uncertainty for vapor pressures near 1 Pa.

255 compared to a reference correlation for the vapor pressures of n-alkanes; the deviation of the measu

256 l forms (i.e., alpha-UO(3)) that have higher vapor pressures than the refractory form (i.e., UO(2)) d

257 s (e.g., UO(3) vs UO(2)) that have different vapor pressures, significantly affecting uranium transpo

258 include molecules with intermediate or high vapor pressures, such as free fatty acids and semi-volat

259 For SVOCs with higher vapor pressures, which are expected to be predominantly

260 In U.S. adolescents, use of an electronic vapor product was associated with lifetime asthma, and t

261 association was stronger when an electronic vapor product was used together with marijuana, particul

262 nd Main Results: In vitro, exposure to e-cig vapor reduced airway surface liquid hydration and increa

263 Here we find that toluene vapor reduces behavioral flexibility in rodents making r

264 Cannabis vapor reinforcement resulted in strong discrimination be

265 The vapors responsible for new particle formation (NPF), pot

266 VAPOR retrieved references for 257 real whole-genome seq

267 DVME that allow for the rapid collection of vapor samples under thermodynamic conditions are (1) the

268 gs validate a novel animal model of nicotine vapor self-administration in rodents with relevance to e

269 and collectively support the utility of the vapor self-administration model for the preclinical asse

270 Moreover, 3 weeks of daily (1 h) nicotine vapor self-administration produced addiction-like behavi

271 Finally, 3 weeks of daily (1 h) nicotine vapor self-administration produced cardiopulmonary abnor

272 ties and harmful effects of chronic nicotine vapor self-administration.

273 ing is the lack of animal models of nicotine vapor self-administration.

274 onding was controlled by exposure to solvent vapor (solvatochromism) or temperature change (thermochr

275 a: see text]) using gravimetric type dynamic vapor sorption (DVS).

276 and provides rapid insight into the type of vapor source(s).

277 with vehicle (polypropylene glycol/glycerol) vapor, suggesting low positive reinforcing effects and l

278 omizing bulk water but also condensing water vapor, suggesting that spontaneous water oxidation to fo

279 n film-stabilizing mechanisms are the liquid-vapor surface tension-driven transport of vapor mass and

280 anges in the presence of solvents or solvent vapor that are rapid, passive, reversible, and easily de

281 (2)x10(-4) S cm(-1) upon treatment with I(2) vapor, the 3D p-POP is the first member of a new class o

282 mperatures and spontaneously reacquire water vapor to form aqueous solutions at low temperatures.

283 ssumes a direct transition of water from the vapor to the ice phase, without an intermediate liquid p

284 s voluntarily exposed themselves to nicotine vapor to the point of reaching blood nicotine levels tha

285 in thickness, opacity, solubility, and water vapor transmission rate (WVTR) analyzes was based on a h

286 hermore, the mechanical properties and water vapor transmission rate (WVTR) of the fabricated bionano

287 helf-life was due to the extremely low water vapor transmission rate of the films, decreasing the fru

288 Simultaneously, intensified water vapor transport from the tropical Pacific and Atlantic i

289 2 predicted alloys using a scalable chemical vapor transport method.

290 internal volume, (2) the use of a capillary vapor trap to minimize the internal volume, (3) the use

291 microglia and a chronic intermittent ethanol vapor two-bottle choice drinking procedure.

292 1) gas inclusions of dense CO(2), (2) liquid-vapor two-phase aqueous inclusions, (3) three-phase incl

293 terfacial instability, and the nucleation of vapor upon multiple non-terminal liquid-solid contacts.

294 The cage crystals exhibit high iodine vapor uptake (3.78 g g(-1) ), which is among the highest

295 the neurobiological interactions of toluene vapor using animal models is important for developing ef

296 to nearly 100 wt.%) condensed from generated vapors via flexible tuning of the carrier gas stream.

297 id can be efficiently removed in the form of vapors via inert gas stream flowing through the PSE laye

298 Lever pressing behavior with nicotine vapor was pharmacologically prevented by the alpha4beta2

299 way with and without the existence of sodium vapor, which is easily adsorbed by kaolinite.

300 The solid receptor is porous to gases and vapors, yielding an uptake of ca. 4 mmol/g for methanol