ライフサイエンスコーパス: fabrication

1 ng an MDL, i.e., even before putting it into fabrication.

2 er and broadens the methods for nanomaterial fabrication.

3 g coherence times and potential for scalable fabrication.

4 livery to microfluidics and from ablation to fabrication.

5 with great ease in fabrication.

6 need for a clean-room environment for device fabrication.

7 tionalities without the need for custom chip fabrication.

8 tem-specific, which limits designability and fabrication.

9 cells and usually require cell seeding post-fabrication.

10 in a polymer matrix on SiO(2) for large-area fabrication.

11 aphic models required less time and cost for fabrication.

12 behavior, medical diagnostics, and material fabrication.

13 rier transportation in optoelectronic device fabrication.

14 ections to complete transistors and circuits fabrication.

15 size of extrinsic defects introduced during fabrication.

16 frameworks with great potential in scalable fabrications.

17 d to complete, including microfluidic device fabrication (2 d), cell seeding (1 d), and progressive d

18 Among methods for device fabrication, 3D printing has emerged as a potential appr

19 A-based cross-linking pathways during byssus fabrication, achieved by oxidative covalent cross-linkin

20 le attributes including compact size, simple fabrication, affordable cost, non-ionizing nature, and m

21 ydrogel constructs through microlithographic fabrication and 3-D printing.

22 que properties, will be inspiring for device fabrication and applications of the transition metal dic

23 ique hold tremendous promise in nanomaterial fabrication and biotechnology.

24 This study demonstrates the fabrication and characterization of an individually addr

25 Experimental advances in the fabrication and characterization of few-layer materials

26 In this work, we introduce the fabrication and characterization of the first ever docum

27 nic devices combine high-performance, simple fabrication and distinctive form factors.

28 First, we focused on the fabrication and doping of LDG platforms using different

29 Ultimately, material fabrication and exploration of interactivity become inse

30 esults indicate that, if the challenges with fabrication and implementation in devices are overcome,

31 However, the fabrication and integration of 3D nanophotonic structure

32 he first report demonstrating peptide matrix fabrication and its application for small explosive mole

33 ounts current limitations of high-throughput fabrication and low energy density of micro-supercapacit

34 The scalable fabrication and manipulation followed by light-directed

35 We present the design, fabrication and response of a humidity sensor based on e

36 twisted-bilayer graphene poses challenges to fabrication and scalability.

37 Here, we demonstrate the fabrication and stabilisation of electrically-tunable de

38 ngineering strategies, including biomaterial fabrication and templating, might be used to overcome ex

39 complicates cross-link regulation, hampering fabrication and the long-term stability/performance of m

40 gnostic platforms, they stand short of batch fabrication and they are dependent on complementary comp

41 This protocol describes the design, fabrication and use of a 3D physiological and pathophysi

42 ng a pathway appropriate for meter-scale PDS fabrication and widespread use for other wavelength shif

43 that can withstand high temperatures during fabrication and, at the same time, can be sacrificed dur

44 This Minireview not only summarizes the fabrications and applications of PAs in catalysis but al

45 The synergistic steps of design, fabrication, and biomimetic in vitro validation and in v

46 In this article we report the design, fabrication, and characterization of three different amo

47 We present the design, fabrication, and measurement results of an angle-sensing

48 Here, the design, fabrication, and modeling of soft electrothermal actuato

49 Here, we demonstrate the design, fabrication, and use of a metal-free (i.e., LSPR-free),

50 us framework membranes, where the chemistry, fabrications, and differences among these membranes have

51 eyond the sole prism of being an alternative fabrication approach.

52 ext, we summarize the bottom-up and top-down fabrication approaches and physical properties of organi

53 ere, we report materials, device designs and fabrication approaches for integrating advanced electron

54 hat are difficult to achieve by conventional fabrication approaches.

55 echanisms by which they emerge during sample fabrication are understood.

56 the ATR module is 10.5 h, enabling overnight fabrication at a total cost ranging from 150 to 613 euro

57 While top-down fabrication based on conventional bulk materials has ena

58 Herein we report synthetic proton channels fabrication based on sulfonated metal-organic frameworks

59 However, the scalable electrode fabrication based on this type of material usually suffe

60 etina of the biological eye pose an enormous fabrication challenge for biomimetic devices(2,3).

61 ves cost- and complexity-related large-scale fabrication challenges and improves multilayer sensitivi

62 This is the first report on the fabrication, characterisation and application of an elec

63 ed by four typical examples, including their fabrication, characterization, and potential limitation.

64 In this report, we describe the fabrication, characterization, and use of a massive arra

65 nsor/analyte interactions, design rationale, fabrication, characterization, sensitivity, and selectiv

66 ed in nature and to which precise optical or fabrication constraints they respond.

67 subject to critical challenges, such as high fabrication costs, thermal drift, sensitivity to moistur

68 efore, it becomes critical to understand how fabrication errors still do affect the performance of MD

69 The proposed method of fabrication expands the design space for hydrogel ionotr

70 on-based approaches including fused filament fabrication (FFF), jetting technologies including inkjet

71 s will potentially lead to accessible device fabrication for 'on-demand' applications.

72 to order transition while bridging materials fabrication from nano- to macroscale remains a challenge

73 fferent aspects of biomedical m-bots: design/fabrication, functionalization, actuation, and localizat

74 rimary choice but due to the difficulties in fabrication, GaP thin films deposited on transparent sub

75 o a variety of host substrates for circuitry fabrication has been among the most popular subjects sin

76 Ultra-long metal nanowires and their facile fabrication have been long sought after as they promise

77 f their excellent properties such as ease of fabrication, higher mechanical properties, high thermal

78 THz regime) to analyse the impact of various fabrication imperfections (single and multiple) on the f

79 t trends in biophotonic materials design and fabrication, including current issues, critical needs, a

80 ces very strong in many processes related to fabrication, integration and performance of devices inco

81 The fabrication is CMOS compatible, demonstrating data trans

82 nd the martensitic transformation during the fabrication leads to complex microstructure hierarchies

83 drawbacks, including energetically expensive fabrication, limited availability of certain constituent

84 orm, which is fully compatible with the CMOS fabrication line, and has potential applications such as

85 However, complicated fabrication, long measurement time, and low sensitivity

86 e fields of drug delivery and medical device fabrication, material examples and the advantages they p

87 Existing studies attest to the importance of fabrication mechanisms and parameters.

88 This is achieved through a top-down fabrication method in which a macroscale preform is ther

89 An additional challenge is to develop a fabrication method that enables the generation of proper

90 nkjet-printing in particular is a compatible fabrication method, widening the range of electronic mat

91 ng materials, is found to be governed by the fabrication method, with those materials obtained via el

92 cluded wt% of PEDOT:PSS and were agnostic of fabrication method.

93 However, current fabrication methods are costly and time-consuming and ha

94 However, these applications require fabrication methods capable of preparing complex, hetero

95 , hardening time, encapsulation and emulsion fabrication methods was studied on loading capacity of t

96 ary of their structures, working mechanisms, fabrication methods, and output performance is provided.

97 This design relies only on traditional fabrication methods, such as machining, casting, and pol

98 We discuss the sensor fabrication methods, the materials and nanostructures in

99 ithout fusion, as compared with conventional fabrication methods.

100 performance based on emerging materials and fabrication methods.

101 capsulants, which not only made the liposome fabrication much easier without the need for purificatio

102 ting, introduces novel opportunities for the fabrication of "smart" or stimuli-responsive devices.

103 ing approaches for large-scale synthesis and fabrication of 2D TMD electronics with naturally formed

104 synthetic flexibility and electronic design, fabrication of 2DPs that form electronically coupled 2D

105 particles can be used as building blocks for fabrication of 3D scaffolds intended for bone tissue eng

106 Here we describe the fabrication of a 16-channel intraneural electrode array

107 drogenase), via EDC/S-NHS chemistry, for the fabrication of a Bio-Nano-PEDOT-based biosensor for lact

108 Here, we report the fabrication of a biodegradable polymeric patch for bucca

109 theory-guided atomic design strategy for the fabrication of a NiGa intermetallic catalyst with comple

110 , enzyme, and cotton wool filter, allows the fabrication of a novel electroanalytical platform that d

111 Here we presented the fabrication of a recombinant fusion protein from recombi

112 h ultrasonication and Span-80 can assist the fabrication of a stabilized nano-emulsion.

113 Also, the second application involved the fabrication of a tyrosinase-based biosensor capable of d

114 Herein, we present the fabrication of a well-defined graphene-like t-COF on Au(

115 he lack of structuring techniques for the 3D fabrication of active materials with long-range periodic

116 ose has received particular attention in the fabrication of advanced delivery systems as sophisticate

117 ironment, which makes them promising for the fabrication of advanced nanomaterials and devices for di

118 d based upon coaxial electrospinning for the fabrication of aligned microfibers engraved with nanosca

119 Fabrication of an ion exchanger microchannel, capable of

120 These advances enable the deterministic fabrication of arbitrary vertical heterostructures and m

121 However, the fabrication of architectured electrodes often involves m

122 -assembly methods in the design and scalable fabrication of beyond-periodic and nonbeam-based nano-ar

123 Fabrication of bio-templated metallic structures is limi

124 While the fabrication of bulk high-entropy carbides and borides is

125 developing area, with a special focus on the fabrication of carbon black-based electrodes in the real

126 In the fabrication of cardiac tissue, an important factor is co

127 (nano-PANI:PSS) as a functional ink for the fabrication of catalyst-free NH(4)(+) sensors and enzyme

128 We report two strategies for the fabrication of chimeric amino acid/nucleobase self-repli

129 In particular, fabrication of complex biomimetic structure that are ent

130 s into specific anatomical sites-enables the fabrication of complex structures inside tissues of live

131 insights into 3D droplet packing permit the fabrication of complex synthetic tissues, where precisel

132 ion, photolysis can also be utilized for the fabrication of complicated patterns with high precision,

133 However, the fabrication of conducting polymers has mostly relied on

134 sultant superior printability enables facile fabrication of conducting polymers into high resolution

135 rsible and it is accordingly employed in the fabrication of covalent adaptable networks (CANs) that p

136 A proof-of-concept workflow study for the fabrication of custom orbital exenteration prostheses vi

137 on, based on biological processes, about the fabrication of damage-tolerant composite materials.

138 nd postsynthetic robustness required for the fabrication of device-quality, nanocrystal-based metamat

139 In this review, the synthesis and fabrication of different nanoparticle-hydrogel superstru

140 The fabrication of dynamic, transformable biomaterials that

141 Herein, we have demonstrated the sustainable fabrication of efficient and air-stable PSCs composed of

142 cations of the results are discussed for the fabrication of efficient PSCs.

143 and potentially cheaper alternative for the fabrication of electrically conductive membranes.

144 The fabrication of epitaxial beta-Ga(2)O(3) thin films is ch

145 This sensor platform was then used for fabrication of ferritin immunosensor, using ferritin spe

146 uring manufacturing and the remainder during fabrication of finished steel products.

147 ecomes temperature-independent, allowing the fabrication of flexible and power-free infrared camoufla

148 a provided here shed light on the design and fabrication of flexible interdigitated NSCs that rival s

149 on the removal of the as-grown strain by the fabrication of freestanding nitride films.

150 Herein, we report the fabrication of fully-printed electrochemical sensors usi

151 s at room temperature is crucial towards the fabrication of future molecular devices, e.g., in the fi

152 Rational design and fabrication of graphene nanoarchitectures with multifunc

153 the monolayer heterostructure allows for the fabrication of heterogeneous transistors and photodetect

154 e manufacturing techniques for the automated fabrication of hierarchically organized living construct

155 Fabrication of high-energy-density and high-power-densit

156 Using these films, batch fabrication of high-performance field-effect transistor

157 loy thin films with tunable bandgaps for the fabrication of high-performance SWIR photodetectors are

158 al evaporation at cryogenic temperatures for fabrication of high-performance wafer-scale p-type field

159 Here we report the fabrication of high-yield, high-performance and uniform

160 Engineered tissue constructs require the fabrication of highly perfusable and mature vascular net

161 erefore be applied in vivo, allowing for the fabrication of highly specific microsensors to study NO

162 The findings highlight a way towards the fabrication of hybrid three-dimensional optoelectronics

163 in materials science is demonstrated by the fabrication of hydrogels with specific architectures, ph

164 plest, and still widely used methods for the fabrication of inorganic solids.

165 ells or regions of interest for the targeted fabrication of lamellae and cryo-ET imaging.

166 onstrate a simple technique for the scalable fabrication of lateral heterojunctions via selective che

167 -harvesting phenomena and can accelerate the fabrication of light-harvesting devices.

168 ndings represent a major step forward in the fabrication of light-responsive organic devices.

169 Here, the scalable fabrication of longitudinal MoS(2) nanostructures, i.e.,

170 Next, the membranes are used for the fabrication of mechanically and electrically actuated ca

171 This allows fabrication of membranes with programmable, predetermine

172 Thus, fabrication of metal-halide perovskites with defined cry

173 wo directions have so far not been merged in fabrication of metal-organic coordination networks using

174 esent a simple and scalable approach for the fabrication of metallic glass fibres with nanoscale arch

175 nting technologies have been adopted for the fabrication of microfluidic devices.

176 ach printing technique has merits toward the fabrication of microfluidic devices.

177 l)piperidinium (3AMP) organic spacer for the fabrication of mixed Pb/Sn-based perovskites, exhibiting

178 ar actuators and microcontrollers enable the fabrication of more complex laboratory instruments that

179 ution describes a synthetic strategy for the fabrication of multicomponent colloidal "molecules" with

180 has emerged as most viable approach for the fabrication of nanofibers with several beneficial featur

181 The fabrication of nanomaterials from the top-down gives pre

182 udy provides an alternative approach for the fabrication of new types of high-performance ultraviolet

183 ich is helpful for rational design and tuned fabrication of next-generation electrode materials for s

184 re we demonstrate a concept for the scalable fabrication of nonperiodic, shell-based ceramic material

185 ible, simple, and scalable method toward the fabrication of NPs with high chiral optical activity.

186 esign, 3D printing, and silicone casting for fabrication of orbital prosthesis was developed and vali

187 at the proposed technique can be extended to fabrication of other ultrathin materials, e.g. graphene,

188 be conveniently implemented for the scalable fabrication of photodetectors.

189 The fractal media are used for the fabrication of plasmonic optical gas sensors, achieving

190 Our work provides access to the precise fabrication of polymers featuring diradical character wh

191 Mechanophores enable the design and fabrication of polymers for a variety of applications ra

192 Developing new materials for the fabrication of proton exchange membranes (PEMs) for fuel

193 The design and fabrication of robust metallic states in graphene nanori

194 ransfer-free direct-etching method for batch fabrication of robust ultraclean graphene grids through

195 The fabrication of Ru nanostructures by focused electron bea

196 the thermal evaporation process enables the fabrication of Se(0.32) Te(0.68) -based 42 x 42 focal pl

197 ing high cooling performance, the design and fabrication of selective emitters, with emission strongl

198 e present comparative studies related to the fabrication of self-assembled monolayer (SAM) and the in

199 Precise fabrication of semiconducting carbon nanotubes (CNTs) in

200 a variety of applications, ranging from the fabrication of silicon wafers for microelectronics to th

201 However, the fabrication of singly dispersed bimetallic cluster catal

202 The aim of this study was the fabrication of stable encapsulated cumin essential oil u

203 ion of these control parameters yields rapid fabrication of stimuli-responsive Janus fibers that func

204 Here, a scalable method is shown for the fabrication of strong and highly conducting pure MXene f

205 The achievements in synthesis and fabrication of structural biomaterials by DNA recombinan

206 to decomposition of prior layers during the fabrication of subsequent layers.

207 Scale fabrication of such devices can be readily achieved base

208 However, reliable techniques for the fabrication of such heterojunctions are still at its inf

209 Fabrication of such materials takes advantage of mesosca

210 ell as outline necessary steps for efficient fabrication of such nanocellulose-based filaments with c

211 as dynamic, yet strong, cross-linkers in the fabrication of supramolecular gels, which exhibited exce

212 However, the fabrication of the nano-DESI probe is challenging, which

213 Fabrication of the protein photoelectrochemical cells wi

214 trochemical techniques to confirm successful fabrication of the sensor.

215 Structural and geometrical fabrication of these materials as wires, coils, films, t

216 Fabrication of three-dimensional (3D) structures and fun

217 tal systems that have been developed for the fabrication of two putative heterocycles.

218 ARIP represents an approach for the scalable fabrication of ultra-selective membranes with uniform na

219 This approach paves the way toward the fabrication of ultrafast CMOS-compatible ferroelectric m

220 This study offers new insights into the fabrication of universal POCT devices.

221 od for automated film formation enabling the fabrication of up to 6048 films per day is introduced.

222 nced nanofabrication methods that enable the fabrication of various geometrically structured nanomate

223 amagnetic heavy metal, has been used for the fabrication of various nanoparticles (NPs) with unique s

224 This work describes the low-cost fabrication of waterproof electronic decals (WPEDs): hig

225 ns and expensive equipment/materials, in the fabrication of wearable sweat sensors, have limited thei

226 otovoltaic devices and helps guide design or fabrication of yet higher efficiency OSCs.

227 and outstanding scalability for reproducible fabrication of ZIF-8 membranes.

228 or pixels with a curved microlens, but their fabrication on a curvilinear surface is challenged by th

229 ) is reported without the need for nanoscale fabrication on the alpha-MoO(3).

230 be compatible with advanced microelectronic fabrication on wafers.

231 design that will significantly simplify the fabrication/operation and meanwhile boost the functional

232 eft much debate as to which factors dominate fabrication output quality.

233 We also show scalable strategies for the fabrication, perfusion culture and volumetric analysis o

234 Some of the potential fabrication pitfalls often encountered in MHP based tand

235 this microfluidic platform can simplify the fabrication procedure and produce a large number of orga

236 The fabrication procedure was clean-room-free and robust, in

237 for improving the material quality and nano-fabrication procedures towards more coherent quantum cir

238 medicine; however, it often requires complex fabrication procedures.

239 materials require complex growth and device fabrication procedures.

240 The top-down fabrication process allowed the authors to vary, readily

241 nt THz microstructured fibers show a complex fabrication process and their flexibility is severely re

242 le production of Mfp proteins and the facile fabrication process described provides a new avenue for

243 To optimize the fabrication process for micro-coatings, a self-limiting

244 factors (e.g. reductants and ligands) in the fabrication process limits on-target design, impeding ma

245 The fabrication process of both sensor types was investigate

246 Having regulated the fabrication process of graphene by altering self-assembl

247 spin coating has demonstrated to be a rapid fabrication process of thin layers with high reproducibi

248 Furthermore, we demonstrate that the film fabrication process proceeds through a partial depolymer

249 We employed a two-step fabrication process to ensure an even mixture and distri

250 The fabrication process, physicochemical properties, and pro

251 w interesting properties exploited after the fabrication process.

252 ation of mixed solvents during the electrode fabrication process.

253 in context of their geometry, materials, and fabrication processes as well as recent demonstrations o

254 low work function, and complicated electrode fabrication processes have limited their practical use.

255 e spectroscopy (EIS) are done to monitor the fabrication processes of the aptasensor.

256 To follow the fabrication processes of the magnetic nano-adsorbent, di

257 as a result of their safety, cost-effective fabrication processes, large surface area, high stabilit

258 h improved capacity and potentially scalable fabrication processes.

259 However, the non-scalable fabrication, prolonged sample processing times, and the

260 The unique tissue fabrication properties of the platform, and the conseque

261 w allows for a broad range of cost-effective fabrication protocols.

262 regrowth separates the source/drain and gate fabrication, providing a viable means to improve ohmic c

263 Their fabrication starts with dry spun CNT fibers that are enc

264 Here, design concepts and fabrication strategies for a kirigami-inspired class of

265 ymers for synthetic photonic structures, the fabrication strategies for flexible photonics, and corre

266 we present, for the first time, a bottom-up fabrication strategy to develop plasmonic nanoantenna-ba

267 re has situated 3D printing as an attractive fabrication technique for scaffolds.

268 We anticipate that our defect fabrication technique will enable the realisation of tun

269 ests, owing to its compatibility with planar fabrication techniques and applicability to a diversity

270 application of NLC, along with its different fabrication techniques and associated limitations.

271 their structure-performance correlation and fabrication techniques for each component of GDEs.

272 We compare fabrication techniques for flexible antennas and demonst

273 t the potential of new microscale design and fabrication techniques for realizing viable devices for

274 be either created artificially using modern fabrication techniques involving inorganic materials, or

275 chitectures typically requires sophisticated fabrication techniques such as flow lithography or multi

276 ment of new chromophores, hybrid systems and fabrication techniques to increase the UC quantum yield

277 can be readily achieved based on the current fabrication techniques with negligible extra expense.

278 reover, the compatibility with semiconductor fabrication techniques(21) may allow for scaling to larg

279 Amongst the possible fabrication techniques, electrodeposition has attracted

280 single biodegradable disc, simple design and fabrication techniques, potential automation thereby mak

281 basic classifications, material selections, fabrication techniques, structural designs, and working

282 d paves the way for rationally designed film fabrication techniques.

283 However, existing fabrication technologies cannot create the submicron-sca

284 Innovations in soft material synthesis and fabrication technologies have led to the development of

285 is applicable to other coating processes and fabrication technologies such as hot forging, machining

286 physics and enables alternative competitive fabrication technologies.

287 on of medically approved materials and novel fabrication technology that enables miniaturization and

288 they can be implemented using semiconductor fabrication technology(2-5).

289 cles, troublesome and time-consuming design, fabrication, testing, and optimization procedures are ne

290 ding the boundary conditions by varying post-fabrication the group index of the fundamental mode in a

291 that - under conditions relevant for device fabrication - the large chiroptical effects are caused b

292 After optimizing the column fabrication, the extraction conditions, and the automati

293 ng of morphology, and optimization of device fabrication, the performance of organic solar cells (OSC

294 Fused filament fabrication three-dimensional (3D) printers have been sh

295 ical sensing modalities, materials, systems, fabrication, to applications are summarized and highligh

296 applicability and scalability of the device fabrication, we demonstrate a multitude of different fun

297 om the well-tapped applications in substrate fabrication, we focus on exploring their tracing and sig

298 several advantages such as repeatability of fabrication, wide operating range and small size and wei

299 ery 3D-printed orbital prosthesis using this fabrication workflow produced good symmetry, color match

300 ol step that creates a bottleneck in plasmid fabrication workflows.