ライフサイエンスコーパス: fabrication

1 a manner compatible with integrated-circuit fabrication.

2 field, at room temperature and after device fabrication.

3 wing distortion, elaboration, and even total fabrication.

4 d, to meet the demand for low-cost and rapid fabrication.

5 imits material deposition options for device fabrication.

6 ltiple printing heads and, thus, multiplexed fabrication.

7 uch as inkjet printing to be used for device fabrication.

8 vation, principle and possible strategies of fabrication.

9 n of the device is not fixed at the point of fabrication.

10 ovide optimal film formation for multi-stack fabrication.

11 erms of selective and sensitive chemosensors fabrication.

12 ce (about $0.04), together with the speed of fabrication (about 2 min), are other important features

13 Here, recent advances in the fabrication and application of nanocomposite hydrogels i

14 ective discusses the state of the art in the fabrication and application of reversibly reconfigurable

15 t nanoparticle systems by combining top-down fabrication and bottom-up self-assembly methods.

16 ssembly is a powerful platform for nanoscale fabrication and capture with many different applications

17 A rigorous and systematic fabrication and characterization campaign of different m

18 The design, fabrication and characterization of a novel metamaterial

19 Fabrication and characterization of a surface plasmon re

20 In this paper, we report the fabrication and characterization of deep UV MgZnO semico

21 Here, the fabrication and characterization of OECTs with verticall

22 Recent advances in nanomaterial fabrication and characterization, specifically carbon na

23 electrode material-copper-that offers simple fabrication and competitive performance in electrochemic

24 Here we report the fabrication and electronic characterization of atomicall

25 cost (about 3 cent per gram), simplicity of fabrication and environment-friendliness, these properti

26 The fabrication and manufacturing processes of industrial co

27 rol and coupling schemes that simplify qubit fabrication and operation.

28 Here, we report the fabrication and optical characterization of a biological

29 This paper describes the fabrication and performances of a temperature and a pH s

30 This report presents the fabrication and pressure-driven processing of heterostru

31 uited to the analyte, and how innovations in fabrication and sensing are coupled together in a mutual

32 velength wave manipulation, with the design, fabrication and size advantages associated with surface

33 Here we present fabrication and successfully testing of a highly sensiti

34 This Protocol Extension describes the fabrication and technical procedures for implementing ul

35 Here, we report the design, fabrication and testing of 3D printed microfluidics chip

36 Combined with an easy, cost effective fabrication and the transparency of the polymer, this pl

37 light.Metasurfaces are not adjustable after fabrication, and a critical challenge is to realise a te

38 soft actuator configurations, their design, fabrication, and applications.

39 We present the design, fabrication, and characterization of an infrared (IR) po

40 developments in the areas of antenna design, fabrication, and characterization.

41 chips including cost-effectiveness, ease of fabrication, and ease of use while preserving critical f

42 t also opens new avenues for the processing, fabrication, and functionalization of fluorinated materi

43 However, the design, fabrication, and implementation of artificial muscles ar

44 d of time, due to physical strength, CAD/CAM fabrication, and low cost.

45 nies routinely use copper fibers for blanket fabrication, and these fibers may remain within the blan

46 This novel nano-fabrication approach promises a low-cost, high-throughpu

47 ell-defined lattice orientation.Conventional fabrication approaches for large-size three-dimensional

48 s with highly controlled color, pattern, and fabrication approaches.

49 Conventional top-down fabrications are costly and time-consuming, whereas natu

50 were used not only as support for electrode fabrication but also as separator of the biobattery.

51 The fabrication can be completed in 1-2 weeks, and the devic

52 Our novel biosensor fabrication can be extended to other metal and metal oxi

53 o one donor because their atomic size causes fabrication challenges.

54 ges where combs can be generated, as well as fabrication challenges.

55 Finally, we examine the fabrication compatible PMMA coating as a viable passivat

56 However, the fabrication complexity of complementary metal-oxide-semi

57 acy that represents a significant advance in fabrication complexity.

58 ical specificity, and mimicking experimental fabrication conditions, and which is suited for high-thr

59 The two-step fabrication consists of printing a silver electrode foll

60 ophotonic devices that directly incorporates fabrication constraints.

61 f photovoltaic technology aims to reduce the fabrication cost and improve the power conversion effici

62 asurfaces to optical devices are rare due to fabrication difficulties.

63 ne is suitable for thin-film heterostructure fabrication due to the re-mixing of different two-dimens

64 clean rooms: they provide low-cost access to fabrication equipment such as laser cutters, plotter cut

65 trial-and-error processing cannot guarantee fabrication feasibility because processing-structure rel

66 f the relatively low efficiency, complicated fabrications, high cost, and inability to scale up.

67 rate the tolerance of its properties despite fabrication imperfections.

68 , making it attractive for practicable pixel fabrication in phase-change display applications.

69 We use Metafluidics to share designs and fabrication instructions for both a microfluidic ring-mi

70 This is in part due to challenges in fabrication, integration, and structural control on the

71 O) triblock copolymers, and their subsequent fabrication into polyrotaxane-based lattice cubes by 3D

72 Device fabrication is applicable via current experimental techn

73 the nanoscale; the scaling-up of nanolattice fabrication is currently the major challenge to their wi

74 require a considerable number of design and fabrication iterations leading to long development times

75 ings from practical use, including difficult fabrication, low efficacy, poor toughness, and durabilit

76 ymer self-assembly in solution prior to film fabrication makes solution-state structures critical for

77 g and conformational changes, lipid membrane fabrication, membrane-protein interactions, exosome and

78 were made using a previously reported facile fabrication method (Duay et al.

79 We present a fabrication method compatible with performing PAGE prote

80 potential as a multimaterial multifunctional fabrication method in areas as diverse as electronics, s

81 We report a novel fabrication method of functionalised Bridged Rebar Graph

82 A simple batch fabrication method simultaneously produced 20 individual

83 Our device requires only simple fabrication methods and provides controllable access to

84 We report simple, water-based fabrication methods based on protein self-assembly to ge

85 ave typically relied on serial, direct-write fabrication methods combined with real-space design.

86 The fabrication methods of ZnO materials are briefly introdu

87 The versatile fabrication methods utilized in sensor development, supe

88 gime and required a variety of materials and fabrication methods.

89 will have on the future of analytical device fabrication, miniaturization, and functionalization.

90 d be utilized for the large-scale controlled fabrication of 2D metal-semiconductor junctions for next

91 Conventional 3D bioprinting allows fabrication of 3D scaffolds for biomedical applications.

92 otypes of Dengue virus has been employed for fabrication of a genosensor.

93 We report on the fabrication of a graphene/titanium dioxide nanocomposite

94 We report on the design and fabrication of a hybrid sensor that integrates transmiss

95 The fabrication of a new type of solar cell encapsulation ar

96 This study describes the first fabrication of a novel bimorphological anisotropic bulk

97 This work opens perspectives toward the fabrication of a novel generation of nonsolid multirespo

98 licon wafer; it was followed by lithographic fabrication of a photonic crystal nanocavity array on th

99 Here, we demonstrate design and fabrication of a portable automatic phoropter with no ne

100 n a viologen-modified redox hydrogel for the fabrication of a sensitive hydrogen biosensor By integra

101 The fast light response enables the further fabrication of a solid film that can be repeatedly writt

102 Here we describe the fabrication of a sub-micrometer electrodic cavity, which

103 The design and fabrication of a versatile and low-cost electrochemical-

104 different experimental works that led to the fabrication of active particles based on this principle.

105 opens the door to rapid design and low-cost fabrication of actuation systems for numerous applicatio

106 Facile fabrication of advanced catalysts toward oxygen reductio

107 ere we demonstrate a simple strategy for the fabrication of an open porous 3D self-organized double-h

108 The presented work is devoted to the fabrication of an ultrasensitive homogeneous biosensor f

109 as well as covering the progress made in the fabrication of ASC devices over the last few decades.

110 ned-space thermal dewetting strategy for the fabrication of Au nanocups with tunable diameter, height

111 l as support materials, thereby enabling the fabrication of bioconjugates and heterogeneous catalysts

112 se nanocrystals is a powerful method for the fabrication of biosourced photonic films with a chiral o

113 The present study reports the fabrication of CdSe quantum dot (QD)-sensitized photocat

114 Here, we demonstrate laser-based fabrication of complex 3D structures deep inside silicon

115 viding simple geometric design rules for the fabrication of complex 3D structures.

116 Wafer-scale fabrication of complex nanofluidic systems with integrat

117 The fabrication of complex three-dimensional gold-containing

118 Nanoparticle self-assembly promises scalable fabrication of composite materials with unique propertie

119 s of graphene open new opportunities for the fabrication of composites exhibiting unique structural a

120 here expands the repertoire of tools for the fabrication of covalent organic networks (which are usua

121 A) remains the main material employed in the fabrication of dentures, the aim of this research was to

122 tically on the ability to achieve controlled fabrication of desirable nanostructures, such as nanorib

123 orphs but also lay foundation for controlled fabrication of desired superlattice with tailored proper

124 hese graphene nanoribbons have prevented the fabrication of devices with the desired performance and

125 lift-off patterning for the straightforward fabrication of diverse device structures.

126 These developments have enabled the fabrication of efficient and "pure" blue OLEDs, single-d

127 we discuss recent progress in the design and fabrication of efficient electrochemical genosensors bas

128 nanoparticles [Cys-La(OH)3 NPs] towards the fabrication of efficient immunosensor for non-invasive d

129 Recent developments in the design and fabrication of efficient sensor platforms based on nanos

130 phene as a fundamental building block in the fabrication of electrochemical biosensors and other bioe

131 so opens up new opportunities for the simple fabrication of electrochemical immunosensors for differe

132 emonstrate a simple, sensitive, and low-cost fabrication of electrochemical LOC microfluidic devices

133 The use and fabrication of electronic devices with MOF-based compone

134 applications in the theoretical studies and fabrication of emergent materials and their structures.

135 d conductive filaments allows for the simple fabrication of energy storage devices with bespoke and c

136 Fabrication of epitaxial FeSexTe1-x thin films using pul

137 erged as a low-cost and practical method for fabrication of flexible and disposable electronics devic

138 nique provides a solution for the continuous fabrication of flexible SERS substrate due to its high-s

139 In particular, we consider the fabrication of fluidic channels, masters for polymer rep

140 itical shortage of donor organs via in vitro fabrication of functional biological structures.

141 cal systems, many biomimetic methods suggest fabrication of functional materials with unique physicoc

142 h has emerged as a promising approach to the fabrication of functional nanoscale objects with high sh

143 onomical parameters that are crucial for the fabrication of functional, complex, engineered tissues.

144 Fabrication of functionalized 3D architected materials i

145 n for optimizing and upscaling the bottom-up fabrication of GNRs.

146 We demonstrate rational design and fabrication of hierarchical In2S3-CdIn2S4 heterostructur

147 ndings indicate an efficient pathway for the fabrication of high-performance 2D optoelectronic device

148 cesses that are suitable for the large-scale fabrication of high-performance devices.

149 that recycled jute should be considered for fabrication of high-performance flexible energy storage

150 Our results thus demonstrate successful fabrication of high-performance short-channel field-effe

151 tential of bioprinting techniques toward the fabrication of highly complex biological structures and

152 rn electronics, and may lead to the scalable fabrication of highly performing devices.

153 the approach developed paves the way for the fabrication of highly polarized white light emitters.

154 Here, we demonstrate the wafer-scale fabrication of highly reflective and conductive non-pola

155 g biopolymer hydrogels, is developed for the fabrication of hollow self-folding tubes with unpreceden

156 olyacrylamide concentration and supports the fabrication of individual hydrogels using the small punc

157 This allowed the atom-by-atom fabrication of isolated platinum deposits, ranging from

158 This work focuses on the in-tip fabrication of lanthanum oxide porous monolith and its a

159 Here, the fabrication of large-area (cm(2) ) nanoporous atomically

160 Bioprinting is an emerging technique for the fabrication of living tissues that allows cells to be ar

161 t linking of precursor molecules enables the fabrication of low-dimensional nanostructures, which inc

162 al strategy for the environmentally friendly fabrication of mesoporous metal-organic framework (mMOF)

163 This controlled fabrication of metal organic self-assembled spheres alon

164 structures, which may find applications for fabrication of metamaterials, sensors, plasmonics, and m

165 a potential revolutionary technology for the fabrication of microfluidic devices.

166 of polydimethylsiloxane (PDMS) for the rapid fabrication of microfluidic networks and the utility of

167 f-assembly processes, the authors report the fabrication of monocrystalline blue phase liquid crystal

168 This study reports a method for the fabrication of monodisperse conducting polymer microcups

169 eter and polydispersity, allowing gram-scale fabrication of monodisperse polymersomes within minutes.

170 The fabrication of monodisperse transmembrane barrels formed

171 ium approaches offer a fast and controllable fabrication of multi-scale microstructures, and their sc

172 in a tube-shaped 3D structure, enabling the fabrication of multifunctional inorganic-carbon-polymer

173 Here, we report the fabrication of multifunctional, smart nanoparticle syste

174 It involved the fabrication of nano-hybrid based electrochemical micro f

175 ter, the same principle is being used in the fabrication of nanolattice materials, namely lattice str

176 This study may open up a new avenue in the fabrication of nanostructure functionalized polymeric me

177 lation of cosmetics and insecticides, to the fabrication of nanostructured materials, to the concentr

178 We report results of the studies relating to fabrication of nanostructured metal oxide (NMO) based ca

179 Template-free fabrication of non-spherical polymeric nanoparticles is

180 The fabrication of nonwoven supports by electrospinning was

181 This feature will benefit the fabrication of novel Li-ion controlled electronic device

182 able dynamic zigzag pattern could enable the fabrication of novel photonic devices and architectures,

183 aser deposition or wafer bonding used in the fabrication of NRPS devices.

184 The proposed method enables simple fabrication of objects with complex geometries and preci

185 luding the measurement sciences, but precise fabrication of optical components for high-performance b

186 ophoresis (PAGE), we develop a technique for fabrication of PAGE molecular sieving gels in PDMS micro

187 e, low cost and user-friendly method for the fabrication of paper electrode (PE) using silver nanopar

188 nexpensive, rapid method for high-throughput fabrication of paper-based microfluidics by patterning h

189 ost-effective, and scalable approach for the fabrication of parallel, laterally oriented AOS nanoribb

190 cilitate the characterization of tissues and fabrication of phantoms used for diagnostic and therapeu

191 s by the number of printer passes and by the fabrication of photonic crystal molecules with controlla

192 ,6, current lithography methods do not allow fabrication of photonic devices and functional microelem

193 licon photonics, enabling massively parallel fabrication of photonic structures.

194 ricate flexible SERS substrate including the fabrication of polymer nanostructure arrays and the meta

195 he large-area, cost-efficient self-organized fabrication of practical devices.

196 The results demonstrated that an efficient fabrication of precise dental restoration is achievable

197 Large-scale fabrication of precisely defined nanostructures with tun

198 posite sides of its beta-barrel supports the fabrication of protein-capped ZnS:Mn nanocrystals that e

199 actuator, where prime focus is on design and fabrication of robotic hardware instead of software cont

200 blocks, with potential applicability to the fabrication of scaffolds for cell culture, reconfigurabl

201 ion is made on the technical barriers in the fabrication of scalable constructs that are vascularized

202 Here, we report the design and fabrication of scanning probe tips that combine SECM wit

203 To achieve this, however, requires the fabrication of sensors small enough to insert into a vei

204 al to the development of these robots is the fabrication of soft actuators.

205 nexpensive, prompts us to explore its use in fabrication of solar-driven electrolysis.

206 we propose multimaterial 3D printing for the fabrication of such devices in a single step.

207 The fabrication of such fascinating L-MNPs may provide new i

208 Bulk fabrication of surface patterns with sub-20 nm feature s

209 eagents need to be added) and flexibility of fabrication of the device, together with the high assay

210 The easy method of fabrication of the electrode, which is also inexpensive,

211 Herein, the two-step fabrication of the first inkjet-printed sulfide-selectiv

212 address scale-up issues associated with the fabrication of the inorganic (electrodes) and biological

213 Fabrication of the separating surface, their morphologic

214 However, fabrication of them is very challenging because it requi

215 We hope to inspire the fabrication of these cascaded logic circuits to stimulat

216 complexity and difficulty in the design and fabrication of these polymer networks, and has rarely be

217 These high-aspect-ratio nanosheets allow the fabrication of thin and defect-free coatings that effect

218 Our work paves the way towards the fabrication of thin films of chiral magnets that host ce

219 chnique may provide a new avenue in low cost fabrication of thin-film solar-cells.

220 We demonstrate programmable fabrication of three-dimensional (3D) materials by print

221 ynthesis of hollow micro/nanostructures, the fabrication of three-dimensional electrodes on the basis

222 Here we report the fabrication of THz SAs by transfer coating and inkjet pr

223 , for development of drug therapies, and for fabrication of tissue equivalents that may have applicat

224 ve been regularly observed, while controlled fabrication of TMD nanoribbons remains challenging.

225 his work developed a facile approach for the fabrication of tumor-targeted multi-modal nanotheranosti

226 Our strategy provides new avenues for fabrication of tunable optical metamaterials by manipula

227 e can be employed for the tailored electrode fabrication of various flexible energy harnessing device

228 In this work, we report the fabrication of vertically aligned copper nanowires (v-Cu

229 This paper addresses the fabrication of vertically aligned ZnO@TiO2 multishell na

230 whereas natural self-assembly and bottom-up fabrications often result in high defect density and lim

231 ost, miniaturization, energy efficient, easy fabrication, online monitoring, and the simultaneous sen

232 Optimizations of various probe fabrication parameters are carried to bring out the sens

233 Fabrication parameters, such as writing pressure and spe

234 This approach opens a fabrication path for applications where tailoring the el

235 te source were found to significantly impact fabrication, patterning, conductivity, and electrochemic

236 n this review, we will highlight the various fabrication principles and biomedical applications of av

237 were made using a previously reported simple fabrication process ( Duay et al.

238 cromechanical oscillators with silicon-based fabrication process can be robust against noise sources

239 The facile fabrication process combined with the excellent separati

240 ical sensor on gauze via a unique embroidery fabrication process for quantitative measurements of wou

241 A key step in the fabrication process is a print-pause-print approach for

242 In addition, its fabrication process is fully compatible with existing in

243 The fabrication process is simple, easy and provides a flexi

244 The fabrication process is straightforward and compatible wi

245 ives innovation rather than a lengthy device fabrication process that hinders it.

246 cess can be robust against noise sources and fabrication process variations.

247 The entire immunosensor fabrication process was fast, requiring overall 45min to

248 structure of the T2SL is not altered by the fabrication process, and a minimal elastic relaxation oc

249 of contamination, common mistakes during the fabrication process, and quality-control measures to ens

250 lity of a continuous, on-the-fly, IFE target fabrication process, employing sequential processing ope

251 heir great separation performance and simple fabrication process.

252 g it is not compatible with the real battery fabrication process.

253 These fabrication processes and implementation protocols will

254 The fabrication processes containing laser patterning and we

255 Recently, novel fabrication processes have realised a three-dimensional

256 The required stringent fabrication processes to obtain high quality MgO-barrier

257 natural flocs could be useful for improving fabrication processes, such as in the paper and textile

258 tary metal-oxide semiconductor logic circuit fabrication processes, this strategy extracts a patterne

259 nt with advances in functional materials and fabrication processes.

260 Here, we report a novel fabrication protocol for Hg disc-well ultramicroelectrod

261 Feature provides a reliable and reproducible fabrication protocol for laboratory scale (10 cm(2)) fue

262 In developing the fabrication protocol, we trade-off constraints on materi

263 d on the compatibility of MOFs with existing fabrication protocols and predominant standards.

264 ntegrated circuit architectures, the layered fabrication realizes a three-dimensional integrated circ

265 nguishing properties of MOFs and eliminating fabrication-related obstacles for integration.

266 typically lack integrated sensors and their fabrication requires multi-step lithographic processes.

267 The latest fabrication routes based on refined starting powders and

268 to minimize cost and turnaround time between fabrication runs; thereby, allowing researchers to focus

269 In cytosensors fabrication simple single-step procedure was used which

270 albumin mats have both biocompatibility and fabrication simplicity, they should be applicable to a r

271 Fabrication, simulation, and measurement data have been

272 le nanofluidic structure design, wafer-scale fabrication, single-digit nanometre channels, reliable f

273 Device fabrication started by substrate-scale growth of MoS2 us

274 While different fabrication strategies and geometries of CNT microelectr

275 table is incorporated, which includes sensor fabrication strategies, type of biomarkers, detection st

276 Here we report a scalable fabrication strategy capable of producing nanofluidic ch

277 We see this PAGE-in-PDMS fabrication technique as expanding the application and u

278 y, material-independent, and high-throughput fabrication technique is thus established with a manifol

279 transistor embodiment, we introduce a rapid fabrication technique that implements non-toxic eutectic

280 Using the current fabrication technique, versatile bacteriorhodopsin-based

281 g cost-effective, rapid, and high-throughput fabrication techniques and low-cost recording media.

282 Currently, MEMS fabrication techniques are primarily based on silicon mi

283 etric silicon nitride using state-of-the-art fabrication techniques has led to our development of USR

284 ss in metasurface designs fueled by advanced-fabrication techniques has led to the realization of ult

285 els using a fusion of bottom-up and top-down fabrication techniques over wafer-scale areas.

286 Here, by using advanced 3D fabrication techniques we integrated a microbead on an A

287 Meanwhile, advances in material science, fabrication techniques, and photonic sensing strategies

288 rview of PCs by explaining their structures, fabrication techniques, and sensing principles.

289 icrostructures is limited by the traditional fabrication techniques.

290 This state-of-the-art fabrication technology provides new opportunities for in

291 Here, we describe the fabrication, testing and first field results of the ISCA

292 f used as recognition units for chemosensors fabrication, they outperform natural receptors with thei

293 ial, while drastically reducing the required fabrication times for producing 3D, hierarchical microst

294 tra-small pixels, high reflectivity and post-fabrication tuning through control of the surrounding me

295 tects the surface from the environment after fabrication until dissolved by an ultrapure electrolyte

296 reflection, and is applicable to wafer-scale fabrication using conventional thin film technologies.

297 ple process, and pave the way for solar cell fabrication via scalable methods in the near future.

298 only provides a guideline for the interface fabrication with distinct crystalline phases but also sh

299 of their applications in devices and device fabrication, with emphasis on initiated CVD (iCVD) and o

300 Particularly, the ease of fabrication without losing the chemical and biological p