ライフサイエンスコーパス: functional material

1 ar dynamics and high-throughput searches for functional materials).

2 to the further development of this promising functional material.

3 stitute a completely new class of sheet-like functional material.

4 the optimization of a translucent thermally functional material.

5 t high temperatures as both a structural and functional material.

6 tial organization, i.e., self-assembly, into functional materials.

7 grains, defects, and strain dynamics inside functional materials.

8 are of high interest for the development of functional materials.

9 benefit the design of zeolite composite opto-functional materials.

10 and organizational detail to create advanced functional materials.

11 al triptycenes hold promise in the design of functional materials.

12 ics provides a new avenue to create advanced functional materials.

13 o the recent spring-up of ionic liquid-based functional materials.

14 , natural products, fine chemicals and other functional materials.

15 rogrammable molecular machines and arrays of functional materials.

16 considerable interest as building blocks for functional materials.

17 perties towards the rational design of novel functional materials.

18 ffer a promising platform for generating new functional materials.

19 pes holds great potential for fabrication of functional materials.

20 ructure-property relationships and designing functional materials.

21 ostsynthetic polymerization of the MOFs into functional materials.

22 sue weaves for rapid prototyping of advanced functional materials.

23 used in the production of fine chemicals and functional materials.

24 plications such as photoswitchable drugs and functional materials.

25 systems and in the design of self-assembled functional materials.

26 ll is the fundamental building block of many functional materials.

27 gy transfer and charge generation in organic functional materials.

28 spanning pharmaceuticals, agrochemicals and functional materials.

29 itu forming gels from this diverse family of functional materials.

30 n of new two-dimensional building blocks for functional materials.

31 development of advanced cephalopod-inspired functional materials.

32 d as ingredients for the production of novel functional materials.

33 diverse opportunities for the fabrication of functional materials.

34 hich will be widely applicable to a range of functional materials.

35 erate the design and realization of advanced functional materials.

36 onal design of next-generation melanin-based functional materials.

37 clearance for better biocompatibility of the functional materials.

38 tially acting as a molecular crosslinker for functional materials.

39 able devices integrated in fabrics as active functional materials.

40 of inspiration for the creation of synthetic functional materials.

41 nging aim to provide more diverse CO2 -based functional materials.

42 ic discovery of hitherto missing, realizable functional materials.

43 ral products, pharmaceuticals, as well as in functional materials.

44 ferroelectric or ferroelastic domains in all functional materials.

45 d general synthesis strategy for bioinspired functional materials.

46 in the self-assembly of structurally complex functional materials.

47 etic biological platform for self-assembling functional materials.

48 therapeutics to the atomic manufacturing of functional materials.

49 olling nanocrystal shape and designing novel functional materials.

50 pounds, an exciting future class of advanced functional materials.

51 xplored design space for this broad class of functional materials.

52 d processes enabling the nanoscale design of functional materials.

53 euticals, agrochemicals, polymers, and other functional materials.

54 global topology of domain configurations in functional materials.

55 que insight for the design of supramolecular functional materials.

56 d fabricated for high-throughput printing of functional materials.

57 erties to meet current and future demands in functional materials.

58 gnment, this is ideal for the development of functional materials.

59 rest in using biopolymers directly to create functional materials.

60 ew sense are versatile frameworks for chiral functional materials.

61 unity for the rational and precise design of functional materials.

62 ionally complex, substitutionally disordered functional materials.

63 rchitectures allows bottom-up fabrication of functional materials.

64 component of numerous molecular devices and functional materials.

65 chiral colloidal particles (M13 phage) into functional materials.

66 nsition metal catalysts, and other molecular functional materials.

67 new opportunities in solution processing of functional materials.

68 approach to designing and optimizing various functional materials.

69 or the construction of dynamic, exchangeable functional materials.

70 m-up assembly of nanotubes and nanorods into functional materials.

71 development of the next generation of hybrid functional materials.

72 edral symmetry may lead to the design of new functional materials.

73 bstacles to achieving the rational design of functional materials.

74 e and shape of the tubules and designing new functional materials.

75 w types of biosensors, bio-NEMS devices, and functional materials.

76 nt in natural products, pharmaceuticals, and functional materials.

77 those systems and for the design of advanced functional materials.

78 , a probable mechanism of water oxidation in functional materials.

79 ive and non-native systems to generate novel functional materials.

80 eedstocks to produce important molecules and functional materials.

81 toward artificial biomaterials and advanced functional materials.

82 benefit the manipulation and fabrication of functional materials.

83 rder, ultimately aiding the future design of functional materials.

84 derstanding the microstructural evolution in functional materials.

85 ation routes for syntheses of structured and functional materials.

86 ly unexplored in the field of self-assembled functional materials.

87 open opportunities in tailoring anion-based functional materials.

88 present new platforms for the development of functional materials.

89 the radiation resistance of these important functional materials.

90 otential to contribute to the development of functional materials.

91 at promise for the tailor-made design of new functional materials.

92 es for the construction of even more complex functional materials.

93 a challenge that could yield a range of new functional materials.

94 n of engineered, hierarchical structures and functional materials.

95 iquids are a distinct, and useful, class of (functional) materials.

96 rms of CLRP has vastly expanded the range of functional materials accessible.

97 ryl thioether in bioactive natural products, functional materials, agrochemicals, and pharmaceuticall

98 fabrication of nanostructures and growth of functional materials and are building blocks for devices

99 ctron dynamics and vibrational coherences in functional materials and biological systems.

100 miniaturize electronic devices, develop new functional materials and catalysts.

101 is a powerful approach to build a variety of functional materials and complex supramolecular systems.

102 ies, offering the opportunity to develop new functional materials and composites with novel and promi

103 nd mechanical properties of a broad range of functional materials and composites, but their synthesis

104 fers the exciting prospect of generating new functional materials and devices by combining them in a

105 the different parts of trees as sustainable functional materials and devices for critical applicatio

106 The custom 3D printing of functional materials and devices opens new routes for th

107 ties for the processing of g-C3N4-containing functional materials and devices.

108 et need to turn molecular self-assembly into functional materials and devices.

109 erformance and reliability of graphene-based functional materials and devices.

110 is of advanced breeds of building blocks for functional materials and devices.

111 ign new building blocks for assembling novel functional materials and devices.

112 be employed to produce novel self-assembled functional materials and devices.

113 eric pressure open new ways to form advanced functional materials and devices.

114 natural products and are useful moieties in functional materials and drug design.

115 have revisited and systematically discussed functional materials and even devices derived from trees

116 as accelerated, concomitant with advances in functional materials and fabrication processes.

117 nd synthesis of amyloid-based biological and functional materials and identify new potential fields i

118 ral strategy for the analysis of bioinspired functional materials and may pave the way for rational d

119 s to efficient templates for last-generation functional materials and nanotechnologies.

120 are now being used to search and predict new functional materials and novel compounds.

121 brids which is expected to help building new functional materials and optimize their properties.

122 ew or exotic processes (the synthesis of new functional materials and structures that are otherwise d

123 y useful insight into the development of new functional materials and structures.

124 enhancing interactions of light with various functional materials and structures.

125 ogy is an abundant source of inspiration for functional materials and systems that mimic the function

126 aracter that impacts the development of many functional materials and systems.

127 ioactive molecules, synthetic intermediates, functional materials, and reagents.

128 wards the use of NIL in patterning active or functional materials, and the application of NIL in patt

129 e the optical fibers are constructed and the functional materials are chemically deposited in distinc

130 In nature, sophisticated functional materials are created through hierarchical se

131 that these two seemingly different groups of functional materials are linked by a number of common ap

132 roups in pharmaceuticals, agrochemicals, and functional materials, as well as in bioactive natural pr

133 rial scientists) interested in synthetic and functional material aspects of 1D materials as well as t

134 al capability of in situ characterization of functional materials at multiple length scales during th

135 ers and demonstrates the utility of emerging functional materials based on anion-anion linkages.

136 various applications for nanostructures and functional materials based on IL including directed self

137 r synthesizing TAE-based molecules useful in functional materials, biological imaging and chemical se

138 strates the powerful potential of engineered functional material biomineralization.

139 utline the salient features of this class of functional materials, both in the context of the functio

140 s actively being exploited for the design of functional materials, bottom-up assembly, and molecular

141 employed to study the effects of defects in functional materials, but complications arising from com

142 olecular systems could underpin exciting new functional materials, but it is extremely challenging.

143 ystems could be used to prepare exciting new functional materials, but it is often challenging to con

144 arge field-driven responses is a hallmark of functional materials, but routes to such competition are

145 group region, we envision them to perform as functional materials by design.

146 Many existing functional materials can be described in this way, and t

147 Collective interactions in functional materials can enable novel macroscopic proper

148 Ordering of mobile defects in functional materials can give rise to fundamentally new

149 New functional materials can in principle be created using c

150 mn quantification of defect concentration in functional materials can provide new insights that may l

151 These genotypes, which may offer new functional material, can be recommended for fruit grower

152 Development of light-driven functional materials capable of displaying reversible pr

153 e demonstrate the capabilities of the hybrid functional material carbon nanotubes/aptamer for the cre

154 These functional materials combine the high molar absorptivity

155 However, the generation of three-dimensional functional materials composed of both soft and rigid mic

156 h throughput screens or for the synthesis of functional materials composed of millions of droplets or

157 f electrochromism and electroluminescence in functional materials could lead to single-layer dual ele

158 We report an integrated organic functional material design process that incorporates the

159 onal switching, a valuable tool for advanced functional material design.

160 Functional materials design normally focuses on structur

161 erent combinations to produce a new class of functional materials, designed for specific device appli

162 However, a big challenge in this soft functional material development is to achieve a high pie

163 igh reversible capacity is a crucial goal in functional materials development.

164 onal nanoplates (NPLs) hold great promise as functional materials due to their combination of low dim

165 fer unique ways to study in situ or operando functional materials due to their highly penetrating nat

166 M13 viruses can allow us to coassemble other functional materials (e.g., catalysts and electron trans

167 ibre architectures that, combined with other functional materials, enable new advanced all-in-fibre d

168 ttractive pathway towards the fabrication of functional materials featuring complex heterogeneous arc

169 nd to SiC performance prediction as either a functional material for device applications or a structu

170 ) was designed and synthesized to serve as a functional material for selective recognition of 6-thiog

171 capacity represent an emerging class of new functional materials for a number of bioanalytical and b

172 esearch to enable the design of tailored and functional materials for a variety of properties in fiel

173 entists and place perovskites in the lead of functional materials for advanced technologies.

174 perties of carbon nanostructures and produce functional materials for electrocatalysis, energy conver

175 uctural features in chemically heterogeneous functional materials for electrochemical energy applicat

176 peptides is a versatile strategy to generate functional materials for many applications.

177 ithium-ion batteries and new perspectives of functional materials for next-generation high-energy bat

178 rushes is a commonly used strategy to create functional materials for numerous applications.

179 such as graphene, exhibit great potential as functional materials for numerous novel applications due

180 FMDs were integrated with fabrics as functional materials for protection against mosquito bit

181 iterature on ferroelectrics, and expanded to functional materials for SOFCs, mixed ionic-electronic c

182 f possibilities to synthesize graphene-based functional materials for various applications.

183 AFM and SEM, which is an ideal structure of functional materials for various applications.

184 res is a promising strategy for constructing functional materials from nanoscale components.

185 embly is a key process used by life to build functional materials from the "bottom up." In the last f

186 By investigating a wide variety of functional materials, general criteria for solid-state e

187 "Strain engineering" in functional materials has been widely explored to tailor

188 recent years, the need for new and efficient functional materials has driven the development of CPPs

189 Synthesis of diamond, a multi-functional material, has been a challenge due to very hi

190 These functional materials have potential applications in micr

191 PFs represent a resurging class of promising functional materials, highlighted with diverse applicati

192 s used as a core structure to organize other functional materials in 3D as the shell.

193 omplex transition-metal oxides are important functional materials in areas such as energy and informa

194 tility of metal-organic frameworks (MOFs) as functional materials in electronic devices has been limi

195 onic liquids have received much attention as functional materials in numerous applications, especiall

196 ases and thereby impede the understanding of functional materials in solution.

197 in modern technologies by introducing multi-functional materials in the semiconductor industry.

198 ortant entities in biological systems and as functional materials in their own right.

199 chosen small molecules paves the way to new functional materials in which ferroelectricity and elect

200 anic frameworks make up an emerging class of functional materials in which the included ionic interfa

201 ersatile building block for the synthesis of functional materials (including biodiagnostics, photovol

202 he fan shell Atrina pectinata are non-living functional materials intimately associated with living t

203 ential that exists for the assembly of other functional materials into hierarchical cellular structur

204 t-infused surfaces) (LIS) are a new class of functional materials introduced in 2011.

205 Patterning functional materials is a central challenge across many

206 However, the synthesis of such functional materials is a challenge because of the trade

207 Accelerating the search for functional materials is a challenging problem.

208 ows that the integration of active media and functional materials is a promising approach to the real

209 On-command changes in the emission color of functional materials is a sought-after property in many

210 cal processes that govern the performance of functional materials is essential for the design of next

211 Recycling solid waste as functional materials is important for both environmental

212 a set of criteria for the rational design of functional materials is not yet available, in part becau

213 The facile coupling of DNA to other functional materials makes this an attractive method for

214 This novel bioinspired, functional material not only displays mechanical charact

215 Emerging complex functional materials often have atomic order limited to

216 Multi-layer structure of functional materials often involves the integration of d

217 This strategy of assembling functional materials onto plastics utilizes the surface

218 To understand how hierarchically structured functional materials operate, analytical tools are neede

219 al systems capable of copying and amplifying functional materials or structures.

220 m resolution, patterning and modification of functional materials other than photoresist and is low c

221 How the functional material properties of centrosomes change thr

222 al to provide rapid and efficient control of functional material properties.

223 the properties chart of all known structural-functional materials providing new opportunities for inn

224 ses, can be induced by mechanical loading in functional materials, providing fundamental insight into

225 Self-assembly of nanocrystals into functional materials requires precise control over nanop

226 indole motors offer attractive prospects for functional materials responsive to light.

227 rk has been devoted to nanoscale assembly of functional materials, selective reversible assembly of c

228 ponsive smart or adaptive stimuli responsive functional materials, self-healable materials, with inte

229 sical" routes for the synthesis of inorganic functional materials slowly unfolds.

230 llpoint pen but with multiple "ink sources" (functional material solutions) and with an apparatus tha

231 conventional metal-based SERS platforms with functional materials such as graphene, semiconducting ma

232 The method can be used to produce functional materials such as inorganic semiconductors or

233 is crucial to systematic engineering of new functional materials such as tunable molecular sieves, g

234 Similarly, synthesis of several functional materials (such as nanowires and nanotubes) d

235 The ability to tailor the performance of functional materials, such as semiconductors, via carefu

236 Understanding complex functional materials suffers from needing to capture str

237 In the search for rationally assembled functional materials, superatomic crystals (SACs) have r

238 single-enzyme, aerobic, and aqueous route to functional material synthesis demonstrates the powerful

239 Here, select results on a variety of functional material systems in the field are presented,

240 f a new generation of domain-specific highly functional material systems.

241 tochromic entity can be used to build highly functional materials, thanks to their potential multi-ad

242 Considering that DNA is a functional material that can organize itself and other m

243 bottom-up strategy to design a new class of functional materials that are both strong and tough.

244 ng blocks for the construction of composite, functional materials that are completely assembled from

245 gning high-performance dielectrics and other functional materials that benefit from nanoscale domain

246 s, the perspective of manufacturing low-cost functional materials that can be easily processed over l

247 and DNA in order to utilize nucleic acids as functional materials that can undergo a molecular "switc

248 allowed the preparation of a broad range of functional materials that could not be realized using pr

249 a new class of additive nanomanufacturing of functional materials that enables a wireless, multilayer

250 ution on inorganic surfaces offers access to functional materials that otherwise would be elusive.

251 as gained great interest in the discovery of functional materials, the advancement of reliable models

252 After loading of functional materials, the holes can be closed by means o

253 eveloped to exploit biological molecules for functional materials, the resulting nanostructures and f

254 present in many drugs, natural products, and functional materials; therefore, methodologies of C-S bo

255 the chemical stability needed to be used as functional materials, they often lack the physical stren

256 esents a new approach for the development of functional materials through mechanochemistry, and possi

257 d to provide new strategies for constructing functional materials through metalloligands for challeng

258 delivery vehicles that incorporate multiple functional materials through sequential deposition of po

259 uctures show promise for the organization of functional materials to create nanoelectronic or nano-op

260 As an important family of functional materials, transition metal oxides are genera

261 other topological structures in operando in functional materials under cross field configurations.Im

262 e corresponding chemistry and preparation of functional materials using various biopolymers from tree

263 The operating conditions of functional materials usually involve varying stress fiel

264 The fabrication of functional materials via grain growth engineering implic

265 Relaxor ferroelectrics exemplify a class of functional materials where interplay between disorder an

266 cal properties in designing high-performance functional materials, where cellulose's structure-mechan

267 tructures has the potential to revolutionize functional materials, where independent control over sha

268 tion techniques has enabled some fascinating functional materials which can be driven by ultraviolet,

269 e, we report a highly ordered donor/acceptor functional material, which has been obtained using the p

270 the designing of high glass transition (Tg) functional materials, which also exhibit stimuli-respons

271 These functional materials, which possess compositional and st

272 have opened the possibility to create novel functional materials, whose properties transcend those o

273 olymers are converted in one or few steps to functional materials will be analysed.

274 APPIBr ionic liquid is a unique functional material with a pyrrole moiety which can be p

275 layered-structure MnO2, is an earth-abundant functional material with potential for various energy an

276 r an extensive ground for the engineering of functional materials with advanced optoelectronic proper

277 romising new approach to synthesize designer functional materials with atomic precision.

278 possible in this versatile class of advanced functional materials with broad implications for their s

279 resolve charge density in nanostructures and functional materials with imperfect crystalline structur

280 eening and future discovery of new polymeric functional materials with important biological applicati

281 hly important for the development of various functional materials with macroscopic properties.

282 ntinuous, defined and scalable deposition of functional materials with micrometer spatial resolution

283 rk interpenetration as well as accessing new functional materials with modified and selective sorptio

284 pportunities not only for the development of functional materials with new or enhanced properties but

285 ules, and can be used to construct organized functional materials with pi-conjugated sections.

286 The ability to assemble functional materials with precise spatial arrangements i

287 e nanotube arrays of other photoabsorber and functional materials with precisely controllable design

288 olecules and proteins, is key to engineering functional materials with predesigned structure.

289 ewetting process can be applied to different functional materials with relevance in technological app

290 preparation of three-dimensional (3D) porous functional materials with special wettability is in urge

291 chors, cables, lattices and webs, as well as functional materials with structure-dependent strength a

292 atalysts or templates for the development of functional materials with tailored organizational proper

293 Complex functional materials with three-dimensional micro- or na

294 a step towards the modular assembly of soft functional materials with tunable architectures and dist

295 ny biomimetic methods suggest fabrication of functional materials with unique physicochemical propert

296 lopment of new therapies that combine highly functional materials with unmatched patient- and applica

297 s in the field of octacyanidometallate-based functional materials, with the particular attention to t

298 dynamic localisation, and spatial control of functional materials within MOF crystals are described.

299 tures, e.g., catenanes or rotaxanes, provide functional materials within the area of DNA nanotechnolo

300 onality by directly incorporating a range of functional materials within the multilayers including nu