ライフサイエンスコーパス: fused-silica

1 ch more uniform than for chemically modified fused silica.

2 ed porous junction across a 3-4-mm length of fused silica.

3 achieve dispersion similar to that found in fused silica.

4 n of high-harmonic generation from amorphous fused silica.

5 octadecylsilane self-assembled monolayer on fused silica.

6 he use of economic chip materials instead of fused silica.

7 spectively, using microfluidic chips made of fused silica.

8 20 nm silica NPs is close to the density of fused silica (2.2 g/cm(3)).

9 We report laser-driven shock experiments on fused silica, alpha-quartz, and stishovite yielding equa

10 interface but for two different substrates, fused silica and chromatographic silica gel.

11 dicity by comparing harmonics generated from fused silica and crystalline quartz, which contain the s

12 esponding to dipolar LSPR modes at the metal/fused silica and metal/water interfaces.

13 to self-assembled monolayer silane films on fused silica and oxidized silicon substrates is describe

14 lecular dynamics studies of shock-compressed fused silica and quartz, we find that silica transforms

15 on of different high-pressure phases between fused silica and quartz.

16 proposed for efficient laser modification of fused silica and sapphire by means of a burst of femtose

17 ing use of multivariate reference signals of fused silica and sapphire Raman signals generated from a

18 The combination of fabrication in fused silica and synchrotron radiation allows measuremen

19 y available high-purity samples of graphite, fused silica, and aluminum show respective nanogram per

20 ed monolayer of dimethyloctadecylsiloxane on fused silica; and the four mobile phases were acetonitri

21 ggesting that the strong adsorption sites on fused silica are chemically the same as those on chromat

22 ety of common substrates (Si/SiO2, sapphire, fused silica) as well as samples that were transferred f

23 gen molecular network that forms transparent fused silica at only 650 degrees C.

24 ue of the 2D hole array first patterned into fused silica before conformal coating and conversion, an

25 man signals (e.g., shoulder of the prominent fused silica boson peak (~130 cm(-1)); distinct sapphire

26 an 12 min using a poly(vinyl alcohol)-coated fused-silica 'bubble cell' capillary.

27 Fused silica capillaries (i.d. 50 microm, o.d. 360 micro

28 The fused silica capillaries are prepared by coating anti-TN

29 modal pore distributions were synthesized in fused silica capillaries by catalyst-free polycondensati

30 water for treatment of the inner surfaces of fused silica capillaries have been tested employing an i

31 MEKC) using sodium dodecyl sulfate (SDS) and fused silica capillaries is demonstrated for neutral, ca

32 ty of the separation voltage with 32 cm long fused silica capillaries permanently coated with hydroxy

33 lumns using 150 mum internal diameter (i.d.) fused silica capillaries to ensure compatibility with na

34 s are prepared in situ within fully enclosed fused silica capillaries via self-assembly and radical p

35 The water-treated fused silica capillaries with uniform internal diameter

36 These were coated on fused silica capillaries, and their gas chromatographic

37 n a 50-mum bore and AS18 Latex on 25-um bore fused silica capillaries, for the separation of mixed ca

38 y and viscosity allow them to be coated onto fused silica capillaries.

39 for zero-clearance connection with standard fused silica capillaries.

40 to stop the apparent fluid flow in uncoated fused silica capillaries.

41 The aptamer medium was packed into fused-silica capillaries (50-150-microm i.d.) to form af

42 solution of poly(ethylene oxide) in uncoated fused-silica capillaries allows high-resolution, repeate

43 Furthermore, the fused-silica capillaries are internally coated with poly

44 In this study, fused-silica capillaries are modified using a polyelectr

45 inear array consists of 19 chemically etched fused-silica capillaries arranged with 500 microm (cente

46 esized inside 75-microm i.d., UV-transparent fused-silica capillaries by photopolymerization.

47 porous polymer frits have been fabricated in fused-silica capillaries by the UV photopolymerization o

48 cibly resolved by CIEF using 100-microm-i.d. fused-silica capillaries coated with hydroxypropyl methy

49 In this approach, fused-silica capillaries coated with thin films of physi

50 olutions into the chip was carried out using fused-silica capillaries coupled to two syringes with th

51 low (EOF) for adsorbent and exchanger packed fused-silica capillaries for acetone as the marker incre

52 ed to modify glass microfluidic channels and fused-silica capillaries for electrophoretic separations

53 successfully used in microfluidic chips and fused-silica capillaries for separation of protein sampl

54 The monoliths are fabricated in fused-silica capillaries from lauryl methacrylate (LMA)

55 e for constructing perfectly aligned gaps in fused-silica capillaries has been developed for postcolu

56 Fused-silica capillaries immersed in an aqueous solution

57 en prepared within the confines of untreated fused-silica capillaries in a single step by a simple co

58 en prepared within the confines of untreated fused-silica capillaries in a single step by a simple co

59 The system uses 50 microm i.d. x 40-200 cm fused-silica capillaries packed with 1.4-3-microm porous

60 roteins was carried out using 50-microm-i.d. fused-silica capillaries packed with 5-microm silica bea

61 The RPLC separations used 50-microm-i.d. fused-silica capillaries packed with submicrometer-sized

62 crofabricated emitter array and conventional fused-silica capillaries showed similar spray characteri

63 The vials were fabricated from fused-silica capillaries that provided a transparent con

64 Sol-gel reactions were carried out within fused-silica capillaries that were filled with properly

65 hodamine 6G, are obtained in 100 microm i.d. fused-silica capillaries under CE conditions using runni

66 ion (ESI)-MS can compromise the integrity of fused-silica capillaries via aminolysis of their outer p

67 to mimic the behavior of PDMS microchannels, fused-silica capillaries were coated with PDMS and used

68 e plasmids from a single bacterial colony in fused-silica capillaries were developed.

69 interchangeable CE cartridges with different fused-silica capillaries were used for the DBS elutions

70 Fused-silica capillaries with inner diameters of 33 micr

71 itical water for reproducible preparation of fused-silica capillaries with tapered geometry suitable

72 rcial cIEF apparatus with coated or uncoated fused-silica capillaries, both chemical and hydrodynamic

73 pared, without the need of high pressure, in fused-silica capillaries, by thermally induced in situ c

74 the monolithic material protrudes beyond the fused-silica capillaries, improving the monolith-assiste

75 f the wetting ability of the ionic liquid on fused-silica capillaries, the maximum operating temperat

76 For fused-silica capillaries, the mobility ((5.5 +/- 0.2) x

77 ong, 360 microm i.d.) connected via external fused-silica capillaries.

78 ) was covalently bound to the inner walls of fused-silica capillaries.

79 smotic flow arising from the use of uncoated fused-silica capillaries.

80 acid (pH 2.4) as the background electrolyte, fused silica capillary (67 cm) with a run time below 6 m

81 a 75-mum internal diameter polyimide-coated fused silica capillary (no inside coating) with 60cm tot

82 Construction from a fused silica capillary allows the laser excitation (at 2

83 resis-UV instrument using a polyimide coated fused silica capillary and an in-house designed flow-cel

84 rs ranging from 30 to 300 nm) through a bare fused silica capillary and ultraviolet detection.

85 a lab-made CZE apparatus equipped with bare fused silica capillary and UV-absorption detector operat

86 d reactors constructed with ceramic tubes or fused silica capillary are widely used for combustion in

87 nitors the changes in streaming current in a fused silica capillary as target biomolecules bind to im

88 amples were hydrodynamically injected into a fused silica capillary at 25.0 mbar for 25.0 s.

89 ed by using a specially developed home-built fused silica capillary column stack and a halogen lamp f

90 ed and immobilized in the surface of a bared fused silica capillary column to obtain a magnetic adsor

91 -mer and a 20-mer, were covalently linked to fused silica capillary columns to serve as stationary-ph

92 preparative CE was performed with 180-micron fused silica capillary columns with tapered ends to coll

93 By attaching a fused silica capillary emitter to a vibrating glass slid

94 hieved using both microchip and conventional fused silica capillary emitters, but stable cone-jet mod

95 injection of a single mammalian cell into a fused silica capillary for subsequent analysis by chemic

96 The source was constructed by inserting a fused silica capillary into a stainless steel column enc

97 A bare fused silica capillary is used to separate cationic beta

98 suit the specific application, since common fused silica capillary is used.

99 Fused silica capillary liquid chromatography columns wit

100 icron) are packed directly into laser-pulled fused silica capillary needles from which a spray origin

101 The probe is constructed to spin a fused silica capillary of 530 microns i.d., 700 microns

102 low confines analyte molecules eluted from a fused silica capillary over a planar SERS-active substra

103 the roughened part of the inner surface of a fused silica capillary prepared by etching with supercri

104 s spectrometer was coupled via a deactivated fused silica capillary to an injector of a gas chromatog

105 pplied to a methanol solution flowing in the fused silica capillary to generate an ESI plume at the c

106 nchored to the inner walls of a 0.25 mm i.d. fused silica capillary to produce a sol-gel germania tri

107 in onto the surface of the inner wall of the fused silica capillary tubing.

108 ing for column interfacing with ferrules and fused silica capillary tubing.

109 tic flow (EOF)-assisted separation in a bare fused silica capillary using alkaline pH background elec

110 the coated or untreated inner surface of the fused silica capillary was developed based on the determ

111 50 microm (i.d.) x 38 cm (effective length) fused silica capillary was used for the separation, and

112 ined restriction placed inside a deactivated fused silica capillary was used to increase the cooling

113 side A and stevioside can be determined in a fused silica capillary with an inner diameter of 10mum a

114 The CBORR is a thin-walled fused silica capillary with an inner diameter ranging fr

115 llar electrokinetic chromatography (MEKC) in fused silica capillary with an inner roughened part has

116 cetic acid as background electrolyte using a fused silica capillary with inner diameter of 25 mum and

117 covalent linkage to the inner surface of the fused silica capillary, and the feasibility to modify th

118 ation-exchange monolith was synthesized in a fused silica capillary, and used for solid phase extract

119 esign, based on a metal wire housed within a fused silica capillary, led to the most stable signals o

120 ovalently linked to the inner surface of the fused silica capillary, the array can be reused thousand

121 d makes use of a supercritical water-treated fused silica capillary, the inner surface of which has s

122 ubing from a solvent delivery device and the fused silica capillary, used with SAII, inserted into a

123 opipette needle (tip size ~ 15 um) through a fused silica capillary.

124 l plates in a 60.2 cm, 25 mum inner diameter fused silica capillary.

125 re essentially the same as with an untreated fused silica capillary.

126 Micro-funnel, fabricated from biocompatible fused silica capillary.

127 eversible nanogel in a 10 mum inner diameter fused silica capillary.

128 is based on a generic CZE(EACA) method in a fused silica capillary.

129 ining a pulled glass capillary needle with a fused silica capillary.

130 five-layer polyelectrolyte coatings and bare fused silica capillary.

131 ,000,000 theoretical plates in a 25 mum i.d. fused silica capillary.

132 E) is implemented using a 10 cm total length fused-silica capillary (50 mum i.d., 80 mum o.d.) combin

133 ate-2 mM EDTA buffer (pH 8.75) using a 60-cm fused-silica capillary (50-micron i.d., 35-cm effective

134 The 17 peaks were separated in 19min using a fused-silica capillary (50mum internal diameter, 72cm of

135 buffer, pH 6.0, run buffer, and a 30-cm-long fused-silica capillary (75-microm i.d.) with dopamine, c

136 A single, 7-cm, 20-microm-i.d. fused-silica capillary (total volume, 70 nL), with a tap

137 by isoelectric focusing in a short length of fused-silica capillary after which the resolved proteins

138 130-cm-long, 20-microm-i.d., 150-microm-o.d. fused-silica capillary and by monitoring the m/z range o

139 Cells were aspirated into a fused-silica capillary and lysed, and components were se

140 or C-18) cartridge in-line with an uncoated fused-silica capillary and subsequently released for fre

141 instrument is based on a serially connected fused-silica capillary assembly.

142 sheathless electrospray emitter with a bare fused-silica capillary at pH 6.7.

143 nd TPOX, are coamplified simultaneously in a fused-silica capillary by a hot-air thermocycler.

144 A fused-silica capillary column is contained in a tubular

145 t-column heating is obtained by wrapping the fused-silica capillary column with resistance heater wir

146 ates/m was obtained on a 10 m x 0.25 mm i.d. fused-silica capillary column.

147 Fused-silica capillary columns packed with 1.0-microm no

148 were obtained and packed into 30-microm-i.d. fused-silica capillary columns up to 50 cm in length.

149 A number of sol-gel coated fused-silica capillary columns were prepared using sol-g

150 Fused-silica capillary connecting tubes were sealed into

151 A fused-silica capillary continuously samples headspace ga

152 for a range of acetylcholine concentrations, fused-silica capillary geometries, and operating flow ra

153 yl acridine orange (NAO) are injected into a fused-silica capillary in a solution of carrier ampholyt

154 ethod for pulling extracellular fluid into a fused-silica capillary in contact with the surface of ti

155 mical bonding with the silanol groups on the fused-silica capillary inner surface.

156 ay tip are integrated on a single piece of a fused-silica capillary is described.

157 trometry (ESI-MS) in which the end of a bare fused-silica capillary is immersed into aqueous hydroflu

158 Fused-silica capillary LC columns (25-microm i.d.) with

159 A separation process that occurred in the fused-silica capillary leading to the electrospray tip w

160 o be comparable to that of commercial pulled fused-silica capillary nanospray sources.

161 l from a short sample loading channel, and a fused-silica capillary separation column that connects s

162 y applied across the loading channel and the fused-silica capillary separation column.

163 (ES) containing acetonitrile (ACN) inside a fused-silica capillary that was dipped into the sample.

164 or wall of an (aminoalkyl)silane-derivatized fused-silica capillary tube via a biotin/streptavidin/bi

165 Fused-silica capillary tubes with 50-microm bores have b

166 printing approach for microarrays that uses fused-silica capillary tubes with tapered tips for print

167 The mixture was loaded into 150-micron-i.d. fused-silica capillary tubing with a pulled 5-10-micron

168 tion via alpha-cyclodextrin in an unmodified fused-silica capillary under reversed polarity.

169 rsible binding of conalbumin to the uncoated fused-silica capillary walls.

170 The other fused-silica capillary was connected to a Venturi easy a

171 A single 30-microm-i.d. fused-silica capillary was used both as the reaction ves

172 vely small pressure drop (<100 bar) across a fused-silica capillary which has both the inlet and outl

173 The stationary phase was formed inside a fused-silica capillary whose lumen was coated with coval

174 0-microm-i.d., 150-microm-o.d. underivatized fused-silica capillary with 1 M formic acid as the backg

175 The separation was achieved using fused-silica capillary with buffer constituted of 40 mmo

176 ately 3, 60 muM with a 25 mum inner diameter fused-silica capillary) with good peak symmetry and base

177 Analytes are rapidly separated in the fused-silica capillary, and following separation, high-s

178 otonation conditions were detrimental to the fused-silica capillary, limiting practical use.

179 sensor into a hole drilled in the wall of a fused-silica capillary, which can be easily connected to

180 ) apparatus, constructed using a thin-walled fused-silica capillary, with a benchtop energy-dispersiv

181 roximately 50-cm-long and 500-nm-radius bare fused-silica capillary.

182 olycondensation reactions performed within a fused-silica capillary.

183 ymerized silica-based monolithic column in a fused-silica capillary.

184 otein complexes from polyacrylamide gel to a fused-silica capillary.

185 due to hydrogen bonding to the walls of the fused-silica capillary.

186 s and compared it with results obtained in a fused-silica capillary.

187 the tensile strength of the polyimide coated fused-silica capillary.

188 delivering reagents to the surface through a fused-silica capillary.

189 phoresis using an electrolyte of low pH in a fused-silica capillary.

190 ion, separation, and detection features on a fused silica chip in a dead volume-free manner, all extr

191 -couple and guide laser emission on the same fused-silica chip.

192 ings within pretreated glass capillaries and fused-silica chips.

193 er ionization source via a short deactivated fused silica column.

194 ared with the CZE analysis performed on bare fused-silica columns with traditional sample injections.

195 nts ranging from 10 bp to 5 kb by using bare fused-silica columns.

196 le computed axial lithography (micro-CAL) of fused silica components, by tomographically illuminating

197 design utilizes a short, continuous diameter fused silica conduit, which extends from the point of ab

198 d of the GC column using a two-way press-fit fused-silica connector housed inside the GC injection po

199 ected to the gel column via zero dead volume fused-silica connectors.

200 verlaid section of a multimode optical fiber fused silica core.

201 pump-probe X-ray diffraction measurements on fused silica crystallizing to stishovite on shock compre

202 e system utilized a shearing T-junction in a fused-silica device to generate a stream of monodisperse

203 te wetting of micro- and nanostructures in a fused-silica device with only a single inlet.

204 the second ((2)D) polar columns, deactivated fused silica (DFS) columns, a microfluidic Deans switch

205 e exploit the reflectivity modulation of the fused silica dielectric system in a strong light field t

206 ospray interface, a purpose-built monolithic fused-silica droplet generator chip, and an ultra-fast I

207 The laser damage precursors in subsurface of fused silica (e.g. photosensitive impurities, scratches

208 ithic chromatography support within a pulled fused-silica electrospray needle.

209 arated peptides were ionized using an etched fused-silica emitter capable of stable operation at the

210 irect comparisons with conventional glass or fused silica emitters indicated very similar performance

211 ve developed a new procedure for fabricating fused-silica emitters for electrospray ionization-mass s

212 xtures are then infused into a metal-coated, fused silica ESI emitter for MS analysis.

213 tion function, a physisorbed stilbene dye on fused silica exhibited a narrow distribution centered at

214 A polyacrylate (PA) film was coated onto a fused-silica fiber as a permeation membrane in a membran

215 lification process to the sensing surface of fused silica fibers.

216 elective immobilization of polymerase to the fused silica floor of the ZMW was achieved by passivatio

217 To measure slow desorption from fused silica, fluorescence imaging combined with correla

218 ons smaller than 1 microm were fabricated in fused silica for high-sensitivity single-molecule detect

219 ary isoelectric focusing (CIEF) in a tapered fused silica (FS) capillary with matrix-assisted laser d

220 lase (OPH) were monitored upon adsorption to fused silica (FS) surfaces in the presence of BSA on a m

221 phobic trimethylsilane (TMS) and hydrophilic fused silica (FS) surfaces.

222 Water-filled TAF-clad fused-silica (FS) tubes show the lowest attenuation acro

223 ith smooth surface, comparable to commercial fused silica glass.

224 ulated over 563 +/- 104 optical periods of a fused silica grating structure, powered by a 800-nm-wave

225 phoresis (CE) separations on bare and coated fused silica have been detected on-line using a time-of-

226 The entire flow path is fused silica; inlet and outlet capillary inner diameters

227 The fused-silica-insulated platinum electrodes could be clea

228 ded spectral region was studied at the H(2)O/fused silica interface.

229 the evanescent-field layer (EFL) at a water/fused-silica interface.

230 phenomenon in which the dissolution rate of fused silica is enhanced by more than 5 orders of magnit

231 The column was an uncoated fused-silica-lined stainless steel capillary column.

232 A fused silica liner, placed inside the vaporization micro

233 Furthermore, SML-FSHS required only a bare fused silica microcapillary and simple pressure control

234 The pressure cell consists of a single fused silica microcapillary.

235 Experiments were performed using fused silica microchips with and without octadecyltrimet

236 erchangeable fluid cartridges, a 2-cm-square fused-silica microfluidic chip, and a miniature laser-in

237 Furthermore, we determine conditions in fused silica nanochannels with which to generate optimal

238 dsDNA) oligonucleotides in custom-fabricated fused-silica nanochannels filled with a gel-free sodium

239 Lately, a reversible semimetallization in fused silica on a femtosecond time scale by using a few-

240 l samples to chemically derivatized walls of fused-silica open-tube capillary columns.

241 Physisorption of BSA-Ac onto a fused-silica optical fiber lowers the accessibility of A

242 wed diffusion of fibrinogen relative to bare fused silica or hydrophobically modified fused silica, s

243 nside polymer glass sandwich chips made from fused silica or soda-lime glass.

244 prepared by in situ polymerization in PEEK, fused silica, or stainless steel tubing having an inner

245 erent adsorption behaviors when contact with fused silica, polystyrene, and poly(methyl methacrylate)

246 Second, the time required to make the fused silica porous is reduced from approximately 1 h to

247 adsorbed RPE molecules on the surface of the fused-silica prism were counted with confidence based on

248 between an electrode and the hypotenuse of a fused-silica prism.

249 The mixture flows through a fused silica reactor capillary to a flow-gated interface

250 p-probe XRD measurements on shock-compressed fused silica, revealing an amorphous to crystalline high

251 wide variety of materials including silicon, fused silica, sapphire, thermal oxide, and lithium nioba

252 ion actuators to translate the sample to the fused silica separation capillary, using vials in this w

253 ection of the fluorescence emission from the fused silica separation capillary.

254 quantify the interfacial free energy at the fused silica/single-layer graphene/water interface at pH

255 on copper, silicon carbide, and transparent fused silica (SiO(2)) substrates, enabling optical spect

256 action chambers etched into the surface of a fused silica slide to observe their individual substrate

257 ng greatly improved adhesion of the films to fused silica slides and allowed extensive optical studie

258 be lithographically patterned directly onto fused silica slides without any requirement for further

259 film on a transparent single-layer graphene/fused silica substrate.

260 ethod of high-quality concave microarrays on fused silica substrates based on temporal shaping of fem

261 ent nonlinear vibrational surface spectra of fused silica substrates functionalized with quinuclidine

262 otocol for obtaining silver nanoparticles on fused silica substrates via laser photoreduction of a si

263 e carried out in channels micromachined into fused silica substrates.

264 are fused silica or hydrophobically modified fused silica, suggesting that the mechanism of PEG resis

265 re dip-coated onto an etched and derivatized fused silica support and placed in a high-capacity UV re

266 erization of ionic liquid (IL) monomers on a fused silica support is described.

267 ar-supported lipid bilayers were prepared on fused silica supports using the Langmuir-Blodgett/Langmu

268 paves the way for developing 3D, monolithic, fused silica surface enhance Raman spectroscopy (SERS) m

269 icles of approximately 50 nm diameter on the fused silica surface.

270 of the number of apparent silanol sites on a fused-silica surface has a linear relationship with the

271 in (RPE), an autofluorescent protein, on the fused-silica surface were studied in capillary electroph

272 At a fused-silica surface, molecular conformation and adsorpt

273 E molecules were partially adsorbed onto the fused-silica surface.

274 -nanometer-thick evanescent-field layer at a fused-silica surface.

275 ge resistance of scratched and non-scratched fused silica surfaces after HF etching with high-frequen

276 er density of net-aligned water molecules at fused silica surfaces in contact with aqueous solutions

277 lecules were fabricated on glassy-carbon and fused-silica surfaces.

278 h an inner capillary (usually constructed of fused silica) that is surrounded by an outer stainless-s

279 For the second type of site, for fused silica, the population of DiI is even higher than

280 M to 1.95 muM, with similar sensitivities in fused silica thin bottom chips for one-photon and two-ph

281 e subject single-layer graphene supported on fused silica to cycles of high and low pH, and show that

282 pray interface using a liquid junction and a fused silica transfer capillary.

283 The optical strength of polished fused silica transmissive optics is limited by their sur

284 annealing of the mixed elemental reagents in fused silica tubes as well as in situ (performed at the

285 num between 800 and 1000 degrees C in sealed fused silica tubes.

286 nless steel tube is replaced with Hydroguard fused silica tubing (0.53 mm x 30 m) and two lightweight

287 hrough a metal union linking two sections of fused silica tubing through which solution flows into th

288 fluorinated ethylene propylene and 50-microm fused-silica tubing for use with capillary HPLC analyses

289 from red blood cells (RBCs) as they traverse fused-silica tubing ranging in i.d. from 25 to 75 microm

290 , the carbon fiber emitter in 75-microm-i.d. fused-silica tubing was shown to give ion current compar

291 erythrocytes were not being lysed inside the fused-silica tubing, dog RBCs, which are known to contai

292 ith a simple LED-photodetector pair, 200 mum fused silica U-bent fiber probe and 60 nm (20 x ) AuNP l

293 ase F monolithic reactor was fabricated in a fused silica using glycidyl methacrylate-co-ethylene dim

294 The choice of fiber optic probes (fused silica versus polymer), the optimum size (20, 40,

295 ed-ring resonator hosts were fabricated on a fused-silica wafer and filled with 3,3'-Diethyloxacarboc

296 bserved to adsorb and move at the methylated fused silica-water interface as a function of temperatur

297 s the interfacial free energy density of the fused silica/water interface by a factor of up to 7, whi

298 re bound to DNA 21-mers covalently linked to fused silica/water interfaces maintained at pH 7 and 10

299 microelectrodes insulated with 300 nm thick fused silica were fabricated using contact photolithogra

300 tionary phases, consisting of functionalized fused-silica windows, were investigated with VR-SFG spec