ライフサイエンスコーパス: materials science

1 ale suitable for studies and applications in materials science.

2 hemistry, catalysis, medicinal chemistry and materials science.

3 tionize chemical biology, radiochemistry and materials science.

4 ety of molecular structures in chemistry and materials science.

5 fusion, proton imaging, cancer therapies and materials science.

6 d advanced applications in biotechnology and materials science.

7 ding multiple functions and methodologies in materials science.

8 ntrast in biomedical imaging, microscopy and materials science.

9 uch schemes, they have not been available in materials science.

10 been one of the most interesting problems in materials science.

11 inorganic and organic chemistry, as well as materials science.

12 are seen throughout biology, chemistry, and materials science.

13 mental study of Weyl fermions in physics and materials science.

14 ccessfully utilized in the life sciences and materials science.

15 y branches of science, including biology and materials science.

16 ttracted increasing attention in physics and materials science.

17 nic chemistry, pharmaceutical chemistry, and materials science.

18 ology, geotechnical engineering and concrete materials science.

19 tifs and intermediates in drug discovery and materials science.

20 such assemblies for use in biomolecular and materials science.

21 pplications in environmental remediation and materials science.

22 ontinues to be a central challenge to modern materials science.

23 plicable across the wide field of perovskite materials science.

24 tical applications in chemistry, biology and materials science.

25 d medicinal chemistry, chemical biology, and materials science.

26 l cycles but also for using viral capsids in materials science.

27 f considerable significance in many areas of materials science.

28 eatly hindered by significant limitations in materials science.

29 rade-off has been a long-standing dilemma in materials science.

30 applications in both medicinal chemistry and materials science.

31 potential for application in biomedicine and materials science.

32 m of applications in crystal engineering and materials science.

33 catalysis represents an exciting frontier in materials science.

34 a wide range of biomedical applications and materials science.

35 on that still remains elusive in polymer and materials science.

36 asingly being applied in polymer science and materials science.

37 ntal sciences, archaeology, biomedicine, and materials science.

38 iences, in chemical-biology, in polymers and materials science.

39 st intensively explored carbon allotropes in materials science.

40 onal materials design is an emerging area of materials science.

41 ities for novel applications from biology to materials science.

42 perties with applications in biomedicine and materials science.

43 ields of supramolecular chemistry as well as materials science.

44 ligand systems in homogeneous catalysis and materials science.

45 ological, and medicinal chemistry as well as materials science.

46 s, isoindoles have found wide application in materials science.

47 interest and have potential applications in materials science.

48 at will open new avenues for applications in materials science.

49 cks remains a challenge and central goal for materials science.

50 the interface of biology, biotechnology, and materials science.

51 us in natural products, pharmaceuticals, and materials science.

52 spread importance in chemistry, biology, and materials science.

53 e important in many phenomena in biology and materials science.

54 -like polymers is a fundamental challenge in materials science.

55 l macromolecular interactions in biology and materials science.

56 from fundamental aspects to applications in materials science.

57 entral role in biology and, increasingly, in materials science.

58 ted with quantum electrodynamics rather than materials science.

59 cal to developments in medicine, biology and materials science.

60 glass or gel, is a long-standing problem of materials science.

61 rtant throughout biology, biotechnology, and materials science.

62 research fields including biotechnology and materials science.

63 action data remains a challenging problem in materials science.

64 and would benefit both the creative arts and materials science.

65 , electronic properties, and applications in materials science.

66 of solid-state compounds is a cornerstone of materials science.

67 such diverse areas as molecular medicine and materials science.

68 and vital to chemistry, biology, physics and materials science.

69 asymmetric particles has great potential for materials science.

70 s, is emerging as one of the major topics in materials science.

71 l and chemical processes and increasingly in materials science.

72 egions is a current area of high interest in materials science.

73 g chemistry, geochemistry, biochemistry, and materials science.

74 throughout chemistry, biology, physics, and materials science.

75 pre)catalysts to heterogeneous catalysis and materials science.

76 or heavy materials for advanced research in materials science.

77 property connections and a key challenge in materials science.

78 en the next frontier of condensed matter and materials science.

79 toward the application of boratriazaroles in materials science.

80 able tool in medical diagnosis, biology, and materials science.

81 he full exploitation of these derivatives in materials science.

82 ttest fields in condensed matter physics and materials science.

83 ntil activated have numerous applications in materials science.

84 roader applications to forensic, energy, and materials science.

85 cted to have a broad impact on chemistry and materials science.

86 ns which are at the forefront of research in materials science.

87 erial properties is one of the challenges in materials science.

88 ging applications in biomedical research and materials science.

89 ering, energy, gas storage and separation or materials science.

90 th many applications in chemical biology and materials science.

91 n patterns, which are abundant in nature and materials science.

92 phene became a rising star on the horizon of materials science.

93 d polymorphism still remains a holy grail of materials sciences.

94 of objects is an invaluable tool in life and materials sciences.

95 mistry and, more broadly, in life as well as materials sciences.

96 single-crystal x-ray studies of chemical and materials sciences.

97 ocesses, which are properties of interest in materials sciences.

98 technique widely used in the biological and materials sciences.

99 ifiers and super-acceptors with relevance in materials sciences.

100 tic properties and promising applications in materials sciences.

101 practical applications in biotechnology and materials sciences.

102 ample preparation across the life, earth and materials sciences.

103 and glasses is fundamental to both Earth and Materials Sciences.

104 cations in synthetic chemistry, biology, and materials sciences.

105 ing medicinal chemistry, total synthesis and materials science, a general, selective and step-efficie

106 espite significant advances in computational materials science, a quantitative, parameter-free predic

107 ne in fields such as physics, chemistry, and materials science, among others.

108 ic arrangements opens a new research area in materials science and as a result much interest has been

109 Using a combination of materials science and biological techniques, we investig

110 sts how molecular rotors may be used in soft materials science and biology as sensors.

111 In materials science and biology, optical near-field micros

112 inuing to affect different fields, including materials science and biology.

113 otential applications in physics, chemistry, materials science and biology.

114 We describe its impact in materials science and biology.

115 for engineering colloidal systems for use in materials science and biotechnology.

116 Applications in different fields, e.g. in materials science and catalysis including those in small

117 Advances in materials science and chemistry have led to the developm

118 lectronic-structure problems and problems in materials science and condensed matter physics that can

119 he fields of physical and surface chemistry, materials science and condensed matter physics, but they

120 investigated intensively in recent years in materials science and condensed matter physics.

121 alline material, is a critical phenomenon in materials science and condensed matter physics.

122 e is a rapidly rising star on the horizon of materials science and condensed-matter physics.

123 ch of its current development to advances in materials science and creative optical system designs.

124 antum regime, opening up for applications in materials science and device characterization in solid s

125 and opportunities for this emerging field of materials science and engineering are also discussed.

126 from polymer chemistry, physical chemistry, materials science and engineering disciplines.

127 s the fields of chemistry, physics, biology, materials science and engineering for over half a centur

128 applications at the interface of chemistry, materials science and engineering, and biology.

129 Working at the interface between materials science and engineering, biology, and medicine

130 and opportunities for this emerging area of materials science and engineering.

131 molecular scaffolds hold great promises for materials science and for biological applications.

132 represents the fusion of the art of origami, materials science and functional energy storage devices,

133 research topic in condensed matter physics, materials science and geophysics.

134 mic force microscope (AFM) is widely used in materials science and has found many applications in bio

135 romises to have wide-ranging applications in materials science and in single-particle biological imag

136 viruses are now finding new applications in materials science and medicine.

137 ds significant potential for applications in materials science and medicine.

138 d role as nanoplatforms with applications in materials science and medicine.

139 Advances in materials science and molecular biology followed rapidly

140 has been used, among others, in the frame of materials science and most importantly has also found ve

141 ive perspectives in chemistry, glycobiology, materials science and nanoscience, with a particular sig

142 ments worldwide at rapid pace in the area of materials science and nanotechnology have made it possib

143 of scanning probe lithography and its use in materials science and nanotechnology.

144 ew of emerging applications of native CDs in materials science and nanotechnology.

145 quantitative descriptions of the underlying materials science and optics.

146 lectric materials in information technology, materials science and optoelectronics.

147 interest in using their aryl derivatives in materials science and supramolecular chemistry has risen

148 anocrystals become increasingly important in materials science and technology, due to their optoelect

149 ities with the aid of case studies that span materials science and the interface between the physical

150 basis for research in structural chemistry, materials science and the life sciences, including drug

151 used ion beams, previously restricted to the materials sciences and semiconductor fields, are rapidly

152 ally the range of applications in chemistry, materials science, and biomedicine.

153 y exploited strategy in synthetic chemistry, materials science, and chemical biology.

154 ed electronic structure theories in physics, materials science, and chemistry.

155 actions and phase changes, are ubiquitous in materials science, and developing a capability to observ

156 ant reactions that are employed in medicine, materials science, and energy production.

157 borative efforts from the fields of biology, materials science, and engineering are leading to exciti

158 is currently a grand challenge of chemistry, materials science, and engineering to understand and mim

159 rocesses of relevance in chemistry, biology, materials science, and environmental research.

160 Metal analyses in chemistry, materials science, and environmental science are current

161 nt role in many areas of chemistry, physics, materials science, and geochemistry.

162 e organic synthesis, bioinorganic chemistry, materials science, and industrial catalysis.

163 new field at the intersection of chemistry, materials science, and information technology: infochemi

164 science, which combines chemistry, physics, materials science, and mechanical engineering.

165 Function matters in materials science, and methodologies that provide paths

166 a significant impact on crystal engineering, materials science, and mineralogy.

167 cally in the areas of molecular engineering, materials science, and nanotechnology because of their m

168 With the advance of chemistry, materials science, and nanotechnology, significant progr

169 that are increasingly important in biology, materials science, and nanotechnology.

170 of processes in areas as diverse as biology, materials science, and nanotechnology.

171 capabilities represent a challenge in modern materials science, and new procedures to quickly assess

172 icry, environmental chemistry, geochemistry, materials science, and semiconductors.

173 an important goal shared by nanotechnology, materials science, and supermolecular chemistry.

174 ations in vaccine development, biocatalysis, materials science, and synthetic biology.

175 are important in several areas of chemistry, materials sciences, and device physics.

176 uations in the fields of physical chemistry, materials sciences, and the biological sciences.

177 ing calorimetry (DSC)] is frequently used in materials science applications and is increasingly being

178 to have wide potential for metallurgical and materials science applications where the dynamics of ele

179 profound implications for nanotechnology and materials science applications, offering a previously mi

180 a SL framework that addresses challenges in materials science applications, where datasets are diver

181 ns as mechanochromic dyes in engineering and materials science applications.

182 thesized for potential use in biomedical and materials science applications.

183 ould facilitate diverse biotechnological and materials science applications.

184 ful in their own right in pharmaceutical and materials science applications.

185 diagnostics, gene regulation, medicine, and materials science are also presented.

186 Two biological examples and from materials science are also reconstructed to demonstrate

187 lications in bionanotechnology and synthetic materials science are summarized.

188 as a new paradigm in the field of biological materials science as they can serve as a toolbox for rat

189 Polyfluorinated aromatics are essential to materials science as well as the pharmaceutical and agro

190 ribute to our understanding of chemistry and materials science at the nanoscale.

191 ether, these results demonstrate a powerful, materials science-based solution to the problems of stoc

192 tu ball mill setup has been developed at the Materials Science beamline (Swiss Light Source, Paul Sch

193 s a key goal in condensed-matter physics and materials science because it can be used to stabilize st

194 ad applications in biology, nanoscience, and materials science because of its simple optical design,

195 an development, stem cell biology, genetics, materials science, bioengineering, and tissue engineerin

196 al impact across a range of disciplines from materials science, biomaterials, geology, environmental

197 l monitoring, manufacturing quality control, materials science, biotechnology, and metabolomic invest

198 alogue processes promises to strongly impact materials sciences by offering advanced coatings, adhesi

199 technological, and environmental demands of materials science call for focused and efficient expansi

200 rand extension sites, called dislocations in materials science, can mediate the growth of bacterial c

201 ies can expose new avenues for innovation in materials science, catalysis, and biochemistry.

202 gical repercussions in diverse areas such as materials science, catalysis, biotechnology and biomedic

203 ng been considered a major technological and materials science challenge.

204 e recently attracted much research effort in materials science, chemistry, engineering and physics, i

205 Within materials science, combinatorial methods have been widel

206 ials, together with partnerships between the materials science community and those entrusted with the

207 is platform to find widespread use among the materials science community.

208 A nanostructures represent the confluence of materials science, computer science, biology, and engine

209 egulation of gene suppression, as well as in materials science concerning soft molecular self-assembl

210 ccurately reconstructing textures drawn from materials science, cosmology, and granular media, among

211 een an active area of study in chemistry and materials science dating back to the initial synthesis o

212 y applicable and could significantly enhance materials science design space.

213 ithin the 2D plane and open up new realms in materials science, device physics and engineering.

214 ts, which may find potential applications in materials science, drug delivery, and nanoelectronics.

215 thetic organic chemistry, molecular sensors, materials science, drug discovery, and catalysis.

216 t this has been a long-standing challenge in materials science due to the elusive metastable nature o

217 anic chemical vapor deposition) processes in materials science, e.g. for the production of lanthanide

218 scopy is finding increasing applicability in materials science, effectively enabling the dissection o

219 Examples of the function of [S3] (-) in materials science, electrochemistry, analytical chemistr

220 This idea has driven an enormous materials science engineering effort focused on construc

221 of the most fundamental and studied areas of materials science for a myriad of applications.

222 ading topics in condensed matter physics and materials science for many years.

223 s are interesting because they are useful in materials science (for example to generate thin films) b

224 This fact has long been recognized in materials science, for instance.

225 idely used throughout chemistry, biology and materials science, from in vivo imaging to distance meas

226 r determines aspects of various phenomena in materials science, geology, biology, tribology and nanot

227 ing of cell biology and its integration with materials science has led to technological innovations i

228 articular at its interfaces with biology and materials science, has been recently established through

229 Advances in protein engineering and materials science have contributed to novel nanoscale ta

230 Recent advances in materials science have made it possible to perform photo

231 in molecular biology, organic chemistry, and materials science have recently created several new clas

232 rtical stacks, has created a new paradigm in materials science: heterostructures based on 2D crystals

233 Many relevant challenges in materials science, however, require not only functional

234 iocompatibility make it of great interest to materials science; however, precise control of its biosy

235 Its contribution to materials science in the past and the future should not

236 ty have become a burgeoning research area in materials science in the past decade.

237 red from mammalian cell synthetic biology to materials sciences in order to develop interactive biohy

238 ohelicenes in various disciplines such as in materials science, in nanoscience, in biological chemist

239 ical properties are of central importance to materials sciences, in particular if they depend on exte

240 However, the recent surge in two-dimensional materials science is accompanied by equally great challe

241 Research in materials science is contributing to progress towards a

242 cer biology, immunology, bioengineering, and materials science is important to further enhance the th

243 A critical problem in materials science is the accurate characterization of th

244 One of the central themes in materials science is the structure-property relationship

245 strategies from environmental chemistry and materials science is therefore essential to provide a re

246 Materials science is undergoing a revolution, generating

247 The utility of quinone diazides in materials science is vast and well-documented, yet this

248 ow the convergence of synthetic biology with materials sciences might contribute to the development o

249 ing tool that has found broad application in materials science, nanoscience and biology.

250 have some potential uses in several fields: materials science, nanoscience, chemical biology and sup

251 However, many samples in physics, chemistry, materials science, nanoscience, geology, and biology are

252 s expected to find important applications in materials science, nanoscience, physics, chemistry and b

253 solution is expected to find applications in materials science, nanoscience, solid-state physics and

254 are in the focus of research fields such as materials science, nanotechnology, and biotechnology.

255 In this Review, we discuss the physics and materials science of electrical contacts to carbon nanot

256 Materials science of these systems presents numerous pos

257 Materials science offers microbiologists a wide variety

258 tion in fields such as chemical engineering, materials science, or pharmaceutical and life science.

259 of photoprotecting groups can be applied in materials science, organic synthesis and biological syst

260 Initially the review follows a materials science perspective on preparing bimetallic na

261 From this materials science perspective, a de novo basis for under

262 nsions and materials made from them), from a materials science perspective.

263 Organofluorine chemistry plays a key role in materials science, pharmaceuticals, agrochemicals, and m

264 ds is expected to find broad applications in materials science, physics, chemistry and nanoscience.

265 involve interactions among researchers from materials science, physics, chemistry, computer science,

266 In that applied perspective, materials science plays a paramount role in shaping our

267 fundamental challenge, hindering progress in materials science, porous media, and biomedical imaging.

268 Ultrafast materials science promises optical control of physical p

269 r experiencing high velocity collisions, but materials science regarding the extreme events has been

270 nt great opportunities for the chemistry and materials science research communities.

271 rials behavior are an important component of materials science research, partly because measurements

272 They are also important in materials science research.

273 This capability will be useful in materials science, separations, and quality control of m

274 ography is applicable to both biological and materials science specimens, and may be useful for under

275 roteins, and into processes of importance in materials science, such as nanoparticle synthesis and el

276 the past 20 years has had a major impact on materials science, surface science and various areas of

277 Indeed, applying materials science techniques to ectopic and orthotopic c

278 e insights across biological, geological and materials science that are impossible using either indiv

279 he "blue fog," are among the rising stars in materials science that can potentially be used to develo

280 tic compounds in the biomedical field and in materials science, the present study further expands the

281 applications in both medicinal chemistry and materials science, there have been limited reports on th

282 pments in communications, nanotechnology and materials sciences, there has been extraordinary growth

283 tracking, in fields ranging from biology to materials science to astronomy.

284 ed over the past two decades from electronic materials science to biological applications.

285 een applied in various fields of study, from materials science to biological imaging, exploiting the

286 rough their use in applications ranging from materials science to biology.

287 mportant developments in fields ranging from materials science to biology.

288 tion to a wide range of research fields from materials science to cellular biology.

289 g from mechanical engineering, medicine, and materials science to chemistry.

290 ena and theories in many fields ranging from materials science to early-universe cosmology, and to en

291 anding of nanoscale phenomena in fields from materials science to life science.

292 search fields such as chemistry, physics, or materials science, to mention a few, arguably as no othe

293 s, novel perspectives have been opened up to materials science towards the development of dynamic mat

294 proposed, being highly challenging from the materials science viewpoint and with the golden thread o

295 sis of thin films is a desideratum of modern materials science where a material's properties depend s

296 enable scientists to explore new regimes in materials science where augmented force, field and displ

297 Combining synthetic biology and materials science will enable more advanced studies of c

298 by combining advances in nanotechnology and materials science with CL, new avenues for basic and app

299 citing new branch of crystal engineering and materials science with important implications to nanotec

300 he areas of chemistry, physics, biology, and materials science, yet this environment is difficult to