ライフサイエンスコーパス: quartz

1 cover slip of silicate based glass (such as quartz).

2 t to precipitates, and the surface charge of quartz.

3 lectric or polar compounds such as LiNbO3 or quartz.

4 ching between nucleating Mn (hydr)oxides and quartz.

5 cation of albite to a mixture of jadeite and quartz.

6 onto nanomaghemite and nanomaghemite coated quartz.

7 chieved using these transparent CNT films on quartz.

8 tion of positively charged iron hydroxide on quartz.

9 connected columns with well-mixed illite and quartz.

10 terogeneous growth of Fe(III) (hydr)oxide on quartz.

11 ger than that of the commonly compared alpha-quartz.

12 and mica compared to that between CaCO3 and quartz.

13 d patterns and reaches magnitudes similar to quartz.

14 elasto-optic coefficient larger than that of quartz.

15 ws topological similarities with the mineral quartz.

16 Here we present measurements of alpha-quartz (0001).

17 tometer measurements of the stacked graphene-quartz absorbers demonstrated excellent broadband absorp

18 u adsorbed to goethite, montmorillonite, and quartz across a wide range of pH values.

19 U(VI) adsorbed on quartz and chlorite displayed characteristic individual

20 al spectral intensities of U(VI) adsorbed on quartz and chlorite followed the same trend of fractiona

21 ometres, the intra-crystalline plasticity of quartz and feldspar relieves stress by aseismic creep an

22 arge-scale synthesis of Si3N4 nanobelts from quartz and graphite on a graphite-felt substrate was suc

23 Experiments with both quartz and montmorillonite at 5 muM H2O2 desorbed far le

24 th spectral bands designed to measure clays, quartz and other minerals were released in 2012 for Aust

25 eneration measurement was performed on Z-cut quartz and the local-frame tensor elements were calculat

26 allization in sapphire, calcium fluoride and quartz and to compare this phenomenon and show its remar

27 be simulated by one surface U(VI) species on quartz and two on chlorite.

28 at the interface of anisotropic z-cut alpha-quartz and water under conditions of dynamically changin

29 ven shock experiments on fused silica, alpha-quartz, and stishovite yielding equation-of-state and el

30 of two distinct sizes (2 and 6 nm) formed on quartz, and their sizes remained unchanged throughout th

31 ch as polyethylene terephthalate, glass, and quartz, and to conductor supports, such as indium tin ox

32 anisotropies modulate the competition among quartz- and mica-dominated microscopic damage processes,

33 These highly porous and permeable quartz arenite sandstones are directly analogous to rese

34 uartz depends on the rotation angle of alpha-quartz around the z axis.

35 gases trapped in fluid inclusions of Archean quartz (Barberton, South Africa) that reveal the isotopi

36 ffer small-size alternatives to conventional quartz-based oscillators.

37 The disposable quartz biochip, based on microelectronic components foun

38 t be synthesized directly from uraninite and quartz but can be made by low-temperature precipitation

39 ct to a mixture of UO2 (uraninite) and SiO2 (quartz) by 25.6 +/- 3.9 kJ/mol.

40 super-eruption as a case study to show that quartz can resolve late-stage temporal changes in magmat

41 e presence of Al(3+), Al(3+) adsorption onto quartz changed the surface charge of quartz from negativ

42 ctroscopy investigation of U(VI) adsorbed on quartz-chlorite mixtures with variable mass ratios have

43 ated fluids in the systems COH, SiO2-COH ( + quartz/coesite) and MgO-SiO2-COH ( + forsterite and enst

44 re, we show that both borosilicate glass and quartz contain intrinsic defect colour centres that fluo

45 dicate that, for certain types of samples on quartz crystal balances, application of centrifugal forc

46 Electrochemical quartz crystal microbalance (EQCM) and cyclic voltammetr

47 de as well as on gold-coated electrochemical quartz crystal microbalance (EQCM) electrode by electrop

48 Electrochemical quartz crystal microbalance (EQCM) experiments were used

49 acterized through an in situ electrochemical quartz crystal microbalance (EQCM) study.

50 lkaline fuel cells using the electrochemical quartz crystal microbalance (EQCM) technique.

51 ew interference-free multichannel monolithic quartz crystal microbalance (MQCM) platform for bio-sens

52 sium zinc oxide (MZO) nanostructure-modified quartz crystal microbalance (MZOnano-QCM) biosensor to d

53 Film degradation was monitored with a quartz crystal microbalance (QCM) and electrochemical im

54 onance (SPR) assays, Impedance-based method, Quartz Crystal Microbalance (QCM) and paper based detect

55 work, we describe a combined microarray and quartz crystal microbalance (QCM) approach for the analy

56 We developed a gold fabricated quartz crystal microbalance (QCM) as a post-PCR method o

57 This work reports a novel Quartz Crystal Microbalance (QCM) based method that can

58 ions on unfixed cancer cell surfaces using a quartz crystal microbalance (QCM) biosensor was develope

59 reptavidin) and a rod-shaped DNA (47bp) to a quartz crystal microbalance (QCM) device in a suspended

60 devices, such as simple frequency monitoring quartz crystal microbalance (QCM) devices, have good cli

61 ed surface plasmonic resonance (LSPR) into a quartz crystal microbalance (QCM) for studying biochemic

62 In recent years the quartz crystal microbalance (QCM) has seen an impressive

63 A quartz crystal microbalance (QCM) is a highly sensitive

64 The quartz crystal microbalance (QCM) is a label-free, biose

65 Quartz crystal microbalance (QCM) is frequently used to

66 Through the use of an elevated-temperature quartz crystal microbalance (QCM) method we call microsc

67 To prepare molecular imprinted quartz crystal microbalance (QCM) nanosensor, LOV imprin

68 A quartz crystal microbalance (QCM) sensor platform was us

69 esent study, a sensitive molecular imprinted quartz crystal microbalance (QCM) sensor was prepared by

70 tivity improvement of conventional (5-20MHz) quartz crystal microbalance (QCM) sensors remains an uns

71 A quartz crystal microbalance (QCM) study is performed to

72 ity, by coupling polymer micropillars with a quartz crystal microbalance (QCM) substrate to form a tw

73 Previous attempts, based on the quartz crystal microbalance (QCM) technique, focused on

74 The method uses a quartz crystal microbalance (QCM) to measure the change

75 oth differential pulse voltammetry (DPV) and quartz crystal microbalance (QCM) to verify the changes

76 tless detection, both by electrochemical and Quartz Crystal Microbalance (QCM) transducers and by usi

77 in the force spectroscopy mode combined with quartz crystal microbalance (QCM), both applied to quant

78 y (XPS), scanning electron microscope (SEM), quartz crystal microbalance (QCM), contact angle (CA) an

79 (Con A) and glycogen and Con A-mannan using quartz crystal microbalance (QCM), cost and time efficie

80 de bonds, on a gold substrate was studied by quartz crystal microbalance (QCM), surface plasmon reson

81 onist of dopamine D1 receptor (D1R) by using quartz crystal microbalance (QCM).

82 e of LPS binding measurements via orthogonal quartz crystal microbalance and electrochemical readouts

83 upon air drying, as demonstrated by combined quartz crystal microbalance and ellipsometry measurement

84 (ethylene terephthalate), were studied using quartz crystal microbalance and sum frequency generation

85 aces (on-rate/off-rate) was assessed using a quartz crystal microbalance biosensor revealing an incre

86 Quartz crystal microbalance dissipation (QCM-D) measurem

87 yme film thickness, and the mass uptake from quartz crystal microbalance experiments, correlate with

88 ails of this interaction in combination with quartz crystal microbalance interrogation.

89 Quartz crystal microbalance measurements reveal that the

90 In situ electrochemical quartz crystal microbalance measurements support the NMR

91 agreement with reported values for gold from quartz crystal microbalance measurements.

92 ction of controlled substances using a novel quartz crystal microbalance sensor (QCM).

93 c intermittent titration and electrochemical quartz crystal microbalance studies indicate the kinetic

94 olayers of DNA and particles tethered to the quartz crystal microbalance surface by DNA.

95 bodies are tethered on the gold surface of a quartz crystal microbalance through the photonics immobi

96 (AFM) and the NS1 detection was followed by quartz crystal microbalance with (QCM-D) and without ene

97 Using multiharmonic electrochemical quartz crystal microbalance with dissipation (EQCM-D) mo

98 In this work, quartz crystal microbalance with dissipation (QCM)-based

99 e characterize the formation of OM-SBs using quartz crystal microbalance with dissipation (QCM-D) and

100 onto a gold surface for characterization by quartz crystal microbalance with dissipation (QCM-D) and

101 kinetic surface plasmon resonance (SPR) and quartz crystal microbalance with dissipation (QCM-D) mea

102 tibodies recognition and reversibility using quartz crystal microbalance with dissipation (QCM-D) mea

103 ed at illustrating the potentialities of the quartz crystal microbalance with dissipation (QCM-D) tec

104 The Quartz Crystal Microbalance with dissipation (QCM-D) tec

105 deling of the EPS layers were conducted in a quartz crystal microbalance with dissipation (QCM-D).

106 O2, Fe3O4 and gold was characterized using a quartz crystal microbalance with dissipation (QCM-d).

107 Mass-sensitive quartz crystal microbalance with dissipation monitoring

108 vity of hybridization were investigated by a quartz crystal microbalance with dissipation monitoring

109 nsitive to biomolecular interactions, namely quartz crystal microbalance with dissipation monitoring

110 Here we have employed quartz crystal microbalance with dissipation monitoring

111 We probed this interaction by quartz crystal microbalance with dissipation monitoring

112 e present work focuses on the application of quartz crystal microbalance with dissipation monitoring

113 Herein, we demonstrate the capability of the quartz crystal microbalance with dissipation monitoring

114 Using quartz crystal microbalance with dissipation monitoring

115 equency generation spectroscopies along with quartz crystal microbalance with dissipation monitoring

116 th silica surfaces were investigated using a quartz crystal microbalance with dissipation monitoring

117 rom silica surfaces was investigated using a quartz crystal microbalance with dissipation monitoring

118 HepG2 cells was investigated in situ using a quartz crystal microbalance with dissipation monitoring

119 The sensor consisted on a quartz crystal microbalance with dissipation monitoring

120 in films during enzymatic hydrolysis using a Quartz Crystal Microbalance with Dissipation monitoring

121 By employing quartz crystal microbalance with dissipation monitoring,

122 kinetics of SAv binding are characterized by quartz crystal microbalance with dissipation monitoring,

123 ion of solution pH and ionic strength, using quartz crystal microbalance with dissipation monitoring.

124 novel emerging acoustic technology, namely ''Quartz Crystal Microbalance with Dissipation'' (QCM-D) h

125 Using a Quartz Crystal Microbalance with Dissipation, we were ab

126 ation, isothermal titration calorimetry, and quartz crystal microbalance) for interpreting the nature

127 e film and its swelling were measured with a quartz crystal microbalance, and the effects of fouling

128 ation relies on laborious methods that use a quartz crystal microbalance, atomic force microscope, mi

129 We used a combination of quartz crystal microbalance, circular dichroism, molecul

130 zymes to lignin surfaces, measured using the quartz crystal microbalance, correlates to the hydrophob

131 afted carboxyl groups (1-10%) was done using quartz crystal microbalance, electrochemical impedance s

132 eir transport behavior was characterized via quartz crystal microbalance, sand column, spectrofluorom

133 hocholine (DPPC) phospholipid mixtures using quartz crystal microbalance-based nanoviscosity measurem

134 stance, as verified by simultaneous LSPR and quartz crystal microbalance-dissipation (QCM-D) measurem

135 By contrast, quartz crystal microbalance-dissipation (QCM-D) measurem

136 ment approach that integrates a conventional quartz crystal microbalance-dissipation (QCM-D) setup wi

137 ee biosensing approach based on simultaneous quartz crystal microbalance-dissipation and ellipsometry

138 ed with the gravimetric data obtained with a quartz crystal microbalance.

139 e thio-phosphorylated proteins quantified by quartz crystal microbalance.

140 columns containing glass collectors and on a quartz crystal microbalance.

141 orce-based biosensing technique based on the quartz crystal microbalance.

142 different pHs and ionic strengths (I) using quartz crystal microbalance.

143 motor protein (heavy meromyosin, HMM) using quartz crystal microbalance; and motor bioactivity with

144 vely, were screened on 10 MHz dual-electrode quartz crystal microbalances (QCM).

145 Quartz crystal microbalances (QCMs) have been used in th

146 o each tetrapeptide and deposited onto 20MHz quartz crystal microbalances to construct the gas sensor

147 gold nanoparticles and deposited onto 20 MHz quartz crystal microbalances to realize gas sensors.

148 T we report for the first time that a QCM-D (Quartz Crystal Microbalances with Dissipation) based tec

149 Electrochemical quartz crystal nanobalance (EQCN) is used to monitor the

150 sing flow injection analysis-electrochemical quartz crystal nanobalance (FIA-EQCN) technique.

151 These chemosensors comprised the quartz crystal resonator (QCR) or extended-gate field-ef

152 formate (HCOO(-)) ions at the electrode of a quartz crystal resonator coated with an AAEM film, while

153 Bacteria are adhered to a quartz crystal resonator in an electronic bridge that is

154 lymer (MIP-Nic) film on an Au electrode of a quartz crystal resonator of EQCM by potentiodynamic elec

155 The quartz crystal resonator responding only to mass changes

156 experiments with use of the MIP film-coated quartz crystal resonator, was found to be 5.5.

157 as on an Au-coated glass slide and on an Au-quartz crystal resonator.

158 multaneously deposited on gold electrodes of quartz crystal resonators (Au-QCRs) or Au-glass slides b

159 as immobilized on to the thiol modified gold quartz crystal surface.

160 nd HMF was quantified, using a piezoelectric quartz crystal with gold electrodes coated with a layer

161 We present a very powerful method of quartz-crystal admittance modeling of hydrodynamic solid

162 Additional analyses using Quartz-Crystal Microbalance (QCM) and Differential Scann

163 is of nanometer-thin polyester films using a quartz-crystal microbalance with dissipation monitoring.

164 The immunosensor design was evaluated by quartz-crystal microbalance with dissipation, atomic for

165 chitecture is shown to outperform commercial quartz-crystal microbalances in terms of sensitivity.

166 The electrochemical quartz-crystal nanobalance (EQCN) is an in situ techniqu

167 The electrochemical quartz-crystal nanobalance has been used in electrochemi

168 measures changes in frequency (Deltaf) of a quartz-crystal resonator, which are converted into Delta

169 However, some 40% of the analysed quartz crystals display a decrease in delta(18)O values

170 Overall, Toba quartz crystals exhibit comparatively high delta(18)O va

171 mylopectin were spin-coated onto gold coated quartz crystals with a base frequency of 10 MHz.

172 scent emission measured using a conventional quartz cuvette.

173 and the second-order susceptibility of bulk quartz depends on the rotation angle of alpha-quartz aro

174 Atomization of arsane in a 17 W planar quartz dielectric barrier discharge (DBD) atomizer was o

175 h the unradiogenic Nd-Hf isotope of the host quartz diorite, appears to suggest an ancient juvenile m

176 yl)benzenethiosulfonate (BTS) adlayer-coated quartz disc onto which a structure-switching cocaine apt

177 d surface chemistry imposed on piezoelectric quartz discs.

178 Quartz-enhanced photoacoustic spectroscopy (QEPAS) is a

179 Quartz fiber filters (QFF) were used as a reaction surfa

180 es were actively collected using XAD4-coated quartz fiber filters and XAD2 sorbent tubes.

181 .5) and gas-phase SVOCs were collected using quartz fiber filters followed by PUF/XAD-4/PUF adsorbent

182 Simultaneous samples were also collected on quartz filters for organic and elemental carbon (OC/EC)

183 We collected organic carbon (OC) on quartz filters, quantified different OC components with

184 independent methods: artifact corrected bare-quartz filters, thermodenuder (TD) measurements, and the

185 boxylic acids from plain and KOH impregnated quartz filters.

186 samples were collected using cartridges and quartz filters.

187 mainspring shape supported by a multi-prong quartz fork, the reactor size limit could be overcome by

188 3+) adsorption changed the surface charge of quartz from negative to positive, thus inhibiting the pr

189 on onto quartz changed the surface charge of quartz from negative to positive, which caused the slowe

190 generation, both placed inside a gold-coated quartz glass cylinder.

191 novel "bed of nails"-like approach that uses quartz glass nanopillars to anchor islets, solving a lon

192 ree expressed bacteriorhodopsin coupled to a quartz glass surface in a defined orientation through a

193 In this study, adsorption to quartz, goethite, birnessite, illite, and aquifer sedime

194 The new ternary (quartz/goethite/kaolinite) CA-SCM provides excellent pre

195 d from Cr(OH)3- and Cr0.25Fe0.75(OH)3-coated quartz grains and either mixed with synthetic birnessite

196 alate, increasing significantly in sequence: quartz, granite < basalt, olivine, limestone < gabbro.

197 ions with 0-0.1 mM Cr(III), the particles on quartz grew from 2 to 4 nm within 1 h.

198 age radii of gyration (R(g)) of particles on quartz grew from around 2 to 6 nm in the presence of Na(

199 Our experimental results indicate that quartz has stronger U(VI) adsorption ability per unit su

200 using in situ trace-element measurements of quartz-hosted melt inclusions to demonstrate that modera

201 Here, using in situ measurements of quartz-hosted melt inclusions, the authors demonstrate t

202 ector, an ultraviolet projector and a custom quartz imaging chamber.

203 y nucleation and growth of iron hydroxide on quartz in 0.1 mM Fe(NO3)3 solution in the presence of Na

204 Low vP/vS values require a large addition of quartz in a mostly mafic forearc environment.

205 700 degrees C to form NO2 or NO in a heated quartz inlet.

206 method is the control over the thickness of quartz insulation walls relative to the size of the elec

207 of two waves, the wave reflected by the air/quartz interface and that reflected by the metal nanopar

208 provided new insights on interactions among quartz, iron hydroxide, and metal ions.

209 Quartz is a common phase in high-silica igneous rocks an

210 alpha-quartz is a piezoelectric material, it can be produced a

211 f species or materials in contact with alpha-quartz is discussed along with the implications for cond

212 The crystalline form alpha-quartz is the stable silica polymorph at ambient conditi

213 Our study demonstrates that quartz isotope stratigraphy can resolve magmatic events

214 he phonon dispersion as the evolution from a quartz-like to a rutile-like coordination.

215 An ST 90 degrees -X quartz Love wave device with a layer of SiO2 waveguide w

216 sing columns packed with the same illite and quartz mass however with different spatial patterns and

217 sphate, hydroxyapatite, and phytic acid in a quartz matrix.

218 was investigated using a dissipation crystal quartz microbalance (QCM-D) together with microscopy to

219 graphite at high surface speeds, we use the quartz microbalance technique to measure the impact of d

220 ent include surface plasmon resonance (SPR), quartz microcrystal balance (QMB) and surface acoustic w

221 below 1 mug cm(-2) using an electrochemical quartz microcrystal balance.

222 Coating the inner wall of a quartz nanopipet with a thin layer of carbon yields a na

223 The feasibility of using quartz nanopipets as simple and cost-effective Coulter c

224 gh transmission electron microscopy (TEM) of quartz nanopipets for SECM imaging of single solid-state

225 tion of TEM to demonstrate that laser-pulled quartz nanopipets reproducibly yield not only an extreme

226 ting a platinum nanoparticle at the tip of a quartz nanopipette forming a bipolar nanoelectrode.

227 by electrochemical plating in a laser-pulled quartz nanopipette tip immersed in a liquid gallium/indi

228 by chemical vapor deposition (CVD) inside a quartz nanopipette.

229 Quartz nanopipettes have recently been employed for resi

230 the electron beam not to melt or deform the quartz nanotip without a metal coating.

231 erated by electron-hole recombination within quartz or feldspar; it relies, by default, on destructiv

232 by integrating multiple MoS2 transistors on quartz or flexible substrates with voltage gain in the g

233 The effects of undissolved quartz particles, gas bubbles, and compositional inhomog

234 ate the possibility of using nanometer-sized quartz pipettes with a layer of carbon deposited on the

235 ogeneous (in solution) and heterogeneous (on quartz) precipitation rates of (Fex, Cr1-x)(OH)3 through

236 iagonally opposite barrels of a laser-pulled quartz quadruple-barreled pipet and filling the open cha

237 iagonally opposite barrels of a laser-pulled quartz quadruple-barrelled pipet.

238 ernal standard solution and deposited onto a quartz reflector.

239 s using a Tekran (TK) KCl-coated denuder and quartz regenerable particulate filter method (GOMTK, PBM

240 A hybridization were indicated by changes of quartz resonance frequencies.

241 inium and iron phosphate predominated in the quartz-rich low-P subsoil aggregate.

242 as studied in mixtures of negatively charged quartz sand (QS) and positively charged goethite-coated

243 -nAg) in columns packed with water-saturated quartz sand and the same sand coated with Pseudomonas ae

244 o-second-order model, which implies that the quartz sand exhibited substantial surface heterogeneity

245 per unit length of lightning strikes within quartz sand has a geometric mean of ~1.0 MJ/m, and that

246 The attachment of GO particles onto quartz sand increased significantly with increasing IS.

247 nd aluminium isotopes ((10)Be and (26)Al) in quartz sand removed by deep, ongoing glacial erosion on

248 ominant mechanism for GO attachment onto the quartz sand under the experimental conditions.

249 Quartz sand was used as the porous medium and artificial

250 e surface properties of GO nanoparticles and quartz sand were evaluated by electrophoretic mobility m

251 ene oxide (GO) nanoparticles attachment onto quartz sand were investigated.

252 surfaces and no mobility in porous media of quartz sand, even in the presence of humic acid.

253 e in the attachment of GO nanoparticles onto quartz sand.

254 sediments are composed of approximately 96% quartz-sand and 3-4% fine fractions of kaolinite and goe

255 The contributions of quartz-sand, kaolinite, and goethite to U(VI) adsorption

256 We conducted experiments in quartz sands at low volumetric water contents (theta) to

257 d it with the volume fractions of dissolving quartz (SiO2) particles and the gas phase.

258 tically aligned CNT arrays were drawn onto a quartz slide to form CNT films that constituted the OTE.

259 alpha-l-fucosidase-specific antibody onto a quartz slide was investigated with several bioconjugatio

260 Compared with other quartz sources obtained from pre-leaching processes whic

261 f Life after Treatment for Brain Metastases (QUARTZ) study is a non-inferiority, phase 3 randomised t

262 The acoustic wave sensing platform is a quartz substrate functionalized with an adlayer of S-(11

263 plasmons excited in metal nanoparticles on a quartz substrate is observed and analyzed.

264 n upper gold-coated glass sphere and a lower quartz substrate patterned with an array of subwavelengt

265 ydr)oxide particles had more coverage on the quartz substrate than those in 1 mM and 10 mM IS systems

266 ne wall between adjacent QCM electrodes on a quartz substrate to form inverted-mesa-like structure.

267 The acoustic sensor is constituted of a quartz substrate with interdigitated transducers and a S

268 erot resonators represented by each graphene-quartz substrate.

269 multi walled carbon nanotubes (MWNTs) onto a quartz substrate.

270 t directly heteroepitaxially grown on common quartz substrates by polymer assisted deposition (PAD).

271 on(III) (hydr)oxide nucleation and growth on quartz substrates for systems containing arsenate and ph

272 regime achieved by stacking graphene bearing quartz substrates on a ground plate.

273 Here, we report chiral ZnO films coated on quartz substrates with a hierarchical nanostructure rang

274 strate that for disk resonators on low-index quartz substrates, the electric and magnetic dipole mode

275 e segmented fluorescent composite regions on quartz substrates.

276 n of individual molecular rotary motors on a quartz surface in unprecedented detail.

277 In this study, quartz thickness-shear mode (TSM) resonator sensors were

278 rode, which not only protects the ultrasmall quartz tip but also starts electrodeposition from the ti

279 ressures well beyond that of the known alpha-quartz to rutile polyamorphic (PA) transition.

280 oba, and the crystallisation history of Toba quartz traces an influx of a low-delta(18)O component in

281 as compared to that of a multiple microflame quartz tube atomizer (MMQTA) for atomic absorption spect

282 those from a conventional externally heated quartz tube atomizer (QTA).

283 d to be 65% of that of the externally heated quartz tube atomizer.

284 4 nano-core was synthesized using the closed quartz tube with Teflon cover and microwaved 200 degrees

285 The resonance frequency and Q-factor of the quartz tuning fork (QTF) as well as the trace-gas concen

286 abricated by integrating nanoelectrodes with quartz tuning forks (QTFs).

287 multiwalled nanotube is torn apart between a quartz-tuning-fork-based atomic force microscope (TF-AFM

288 leation and growth of Fe(III) (hydr)oxide on quartz under conditions found in acid mine drainage (at

289 r/(86)Sr of ophiolite epidosites and epidote-quartz veins as constraints.

290 -derived fluids and upward mineralization in quartz veins can explain the range of observed vP/vS val

291 , and the ratio of total particle volumes on quartz was 1.7:3.4:1.0.

292 studies of shock-compressed fused silica and quartz, we find that silica transforms into a poor glass

293 he average radii of gyration of particles on quartz were 5.7 +/- 0.3, 4.6 +/- 0.1, and 3.7 +/- 0.3 nm

294 e, Cr)(OH)3 nanoparticles in solution and on quartz were quantified from 0.1 mM Fe(III) solutions con

295 e transferences, SWCNTs films transferred on quartz were used as working optically UV-vis transparent

296 generated from fused silica and crystalline quartz, which contain the same atomic constituents but d

297 ements showed that only Cr(3+) adsorbed onto quartz, while Cu(2+) and Pb(2+) did not.

298 d a miniature flow cell with interchangeable quartz window carrying immobilized aptamer/quantum dot m

299 surface of the 1.5mm ID, 12microl flow cell quartz window has been modified with the aptamer sensing

300 pparatus consists of a titanium reactor with quartz windows, near-infrared and UV spectroscopic detec