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1 fundamental tasks in inorganic synthesis and materials science.
2 abled important breakthroughs in biology and materials science.
3 lem pertinent across physics, chemistry, and materials science.
4 into one of the most challenging problems in materials science.
5 iology and is increasingly exploited in soft materials science.
6 s fields, attracting tremendous attention in materials science.
7 ination complexes, atmospheric chemistry and materials science.
8 of modern chemistry; from drug discovery to materials science.
9 s in geochemistry, environmental science and materials science.
10 ale suitable for studies and applications in materials science.
11 hemistry, catalysis, medicinal chemistry and materials science.
12 perties with applications in biomedicine and materials science.
13 of amines in synthesis, drug discovery, and materials science.
14 property connections and a key challenge in materials science.
15 th many applications in chemical biology and materials science.
16 tionize chemical biology, radiochemistry and materials science.
17 uch schemes, they have not been available in materials science.
18 nic chemistry, pharmaceutical chemistry, and materials science.
19 tical applications in chemistry, biology and materials science.
20 at will open new avenues for applications in materials science.
21 us in natural products, pharmaceuticals, and materials science.
22 geting the JTE and PJTE, and applications in materials science.
23 from fundamental aspects to applications in materials science.
24 , electronic properties, and applications in materials science.
25 of solid-state compounds is a cornerstone of materials science.
26 such diverse areas as molecular medicine and materials science.
27 and vital to chemistry, biology, physics and materials science.
28 asymmetric particles has great potential for materials science.
29 s, is emerging as one of the major topics in materials science.
30 l and chemical processes and increasingly in materials science.
31 egions is a current area of high interest in materials science.
32 g chemistry, geochemistry, biochemistry, and materials science.
33 throughout chemistry, biology, physics, and materials science.
34 pre)catalysts to heterogeneous catalysis and materials science.
35 or heavy materials for advanced research in materials science.
36 en the next frontier of condensed matter and materials science.
37 toward the application of boratriazaroles in materials science.
38 able tool in medical diagnosis, biology, and materials science.
39 he full exploitation of these derivatives in materials science.
40 ttest fields in condensed matter physics and materials science.
41 ntil activated have numerous applications in materials science.
42 roader applications to forensic, energy, and materials science.
43 cted to have a broad impact on chemistry and materials science.
44 in diverse areas of chemistry, physics, and materials science.
45 d matter physics, solid state chemistry, and materials science.
46 ns which are at the forefront of research in materials science.
47 erial properties is one of the challenges in materials science.
48 ging applications in biomedical research and materials science.
49 ering, energy, gas storage and separation or materials science.
50 ry, drug discovery, inorganic chemistry, and materials science.
51 n patterns, which are abundant in nature and materials science.
52 phene became a rising star on the horizon of materials science.
53 ety of molecular structures in chemistry and materials science.
54 fusion, proton imaging, cancer therapies and materials science.
55 d advanced applications in biotechnology and materials science.
56 ding multiple functions and methodologies in materials science.
57 ntrast in biomedical imaging, microscopy and materials science.
58 been one of the most interesting problems in materials science.
59 inorganic and organic chemistry, as well as materials science.
60 are seen throughout biology, chemistry, and materials science.
61 mental study of Weyl fermions in physics and materials science.
62 ccessfully utilized in the life sciences and materials science.
63 y branches of science, including biology and materials science.
64 ttracted increasing attention in physics and materials science.
65 ology, geotechnical engineering and concrete materials science.
66 tifs and intermediates in drug discovery and materials science.
67 such assemblies for use in biomolecular and materials science.
68 pplications in environmental remediation and materials science.
69 ontinues to be a central challenge to modern materials science.
70 plicable across the wide field of perovskite materials science.
71 d medicinal chemistry, chemical biology, and materials science.
72 l cycles but also for using viral capsids in materials science.
73 f considerable significance in many areas of materials science.
74 eatly hindered by significant limitations in materials science.
75 rade-off has been a long-standing dilemma in materials science.
76 applications in both medicinal chemistry and materials science.
77 as isotope geochemistry, nuclear safety, and materials science.
78 ations in medicinal chemistry, as well as in materials science.
79 eat interest in condensed-matter physics and materials science.
80 (photo)catalysis, bioinorganic chemistry and materials science.
81 m the perspectives of chemistry, physics and materials science.
82 possibilities for innovation in polymer and materials science.
83 across the fields of physics, chemistry, and materials science.
84 d applied interest in chemistry, physics and materials science.
85 ng difficult-to-access degrees of freedom in materials science.
86 ry of functional molecules for medicinal and materials science.
87 ems are found across chemistry, physics, and materials science.
88 ic stability that may offer opportunities in materials science.
89 ve a wide range of potential applications in materials science.
90 eaction which is crucial for applications in materials science.
91 d their applications in chemical biology and materials science.
92 l research, chemical biology, and biomimetic materials science.
93 olling disorder is key to nanotechnology and materials science.
94 hallenging topic in nanocarbon chemistry and materials science.
95 ds which are at the forefront of research in materials science.
96 ch attention in condensed matter physics and materials science.
97 es at the forefront of polymer chemistry and materials science.
98 ample preparation across the life, earth and materials sciences.
99 and glasses is fundamental to both Earth and Materials Sciences.
100 cations in synthetic chemistry, biology, and materials sciences.
101 d polymorphism still remains a holy grail of materials sciences.
102 of objects is an invaluable tool in life and materials sciences.
103 mistry and, more broadly, in life as well as materials sciences.
104 single-crystal x-ray studies of chemical and materials sciences.
105 ocesses, which are properties of interest in materials sciences.
106 technique widely used in the biological and materials sciences.
107 ifiers and super-acceptors with relevance in materials sciences.
108 terest to pharmaceutical, agrochemistry, and materials sciences.
112 ing medicinal chemistry, total synthesis and materials science, a general, selective and step-efficie
114 uld prove highly beneficial in the fields of materials science, analytical chemistry, physical chemis
116 unique biophotonic tools for applications in materials science and bioengineering and may also facili
118 gn and applications of LP-EM for soft matter materials science and biological research are reviewed,
124 en one of the ultimate goals of contemporary materials science and chemistry, and the emulation of ta
125 lectronic-structure problems and problems in materials science and condensed matter physics that can
128 antum regime, opening up for applications in materials science and device characterization in solid s
129 photovoltaic devices, are presented from the materials science and device engineering points of view.
131 and opportunities for this emerging field of materials science and engineering are also discussed.
133 ture are described, and their application in materials science and engineering, biology, medical, and
138 represents the fusion of the art of origami, materials science and functional energy storage devices,
141 a step towards on-chip quantum simulation of materials science and interacting particles in curved sp
145 has been used, among others, in the frame of materials science and most importantly has also found ve
146 ments worldwide at rapid pace in the area of materials science and nanotechnology have made it possib
150 interest in using their aryl derivatives in materials science and supramolecular chemistry has risen
151 of microplasmas of particular importance to materials science and technology include light sources f
152 anocrystals become increasingly important in materials science and technology, due to their optoelect
153 portance of both concepts for experiments in materials science and the benefits that result from incl
154 basis for research in structural chemistry, materials science and the life sciences, including drug
155 ucture-function-activity studies in (electro)materials science and will open up exciting new possibil
156 sses is of utmost importance in contemporary materials science and, in particular, in the realm of re
157 used ion beams, previously restricted to the materials sciences and semiconductor fields, are rapidly
163 actions and phase changes, are ubiquitous in materials science, and developing a capability to observ
164 borative efforts from the fields of biology, materials science, and engineering are leading to exciti
165 is currently a grand challenge of chemistry, materials science, and engineering to understand and mim
171 capabilities represent a challenge in modern materials science, and new procedures to quickly assess
173 ast decade at the intersection of chemistry, materials science, and the biological sciences developin
176 tic interfaces have enabled a broad range of materials science applications and hold promise as adhes
177 icant problem concerning the recent boost in materials science applications of a wide range of beam-s
178 to have wide potential for metallurgical and materials science applications where the dynamics of ele
179 a SL framework that addresses challenges in materials science applications, where datasets are diver
184 hen, applications to some select problems in materials science are highlighted: phase-change material
186 as a new paradigm in the field of biological materials science as they can serve as a toolbox for rat
187 Polyfluorinated aromatics are essential to materials science as well as the pharmaceutical and agro
188 ar chemistry which opens up opportunities in materials science, as shown by colossal thermal expansio
190 r chemists and for scientists with different materials science backgrounds interested in the applicat
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
195 resulting potential is broadly applicable to materials science, biology, and chemistry, and billions
196 ncluding synthesis planning, nanotechnology, materials science, biomaterials, and clinical informatic
197 cted to become game-changers in the field of materials science by bringing new properties into the re
198 Machine learning advances chemistry and materials science by enabling large-scale exploration of
199 rystal size effect is of vital importance in materials science by exerting significant influence on v
200 alogue processes promises to strongly impact materials sciences by offering advanced coatings, adhesi
201 technological, and environmental demands of materials science call for focused and efficient expansi
202 ng biomedical research, medicinal chemistry, materials science, catalysis, and organic synthesis.
204 e recently attracted much research effort in materials science, chemistry, engineering and physics, i
205 to make best use of the current advances in materials science combined with computational design, el
206 A nanostructures represent the confluence of materials science, computer science, biology, and engine
207 knowledge, these embeddings capture complex materials science concepts such as the underlying struct
211 g of beam-sensitive materials and associated materials science discoveries, based on the principles o
212 ts, which may find potential applications in materials science, drug delivery, and nanoelectronics.
214 t this has been a long-standing challenge in materials science due to the elusive metastable nature o
217 astronomy, geoscience, biology, psychology, materials science, engineering, finance and economics.
219 croscopy environment, allowing new nanoscale materials science experiments to be conducted systematic
220 have become the focus of growing interest in materials science for various biomedical and technologic
221 s are interesting because they are useful in materials science (for example to generate thin films) b
222 idely used throughout chemistry, biology and materials science, from in vivo imaging to distance meas
223 r determines aspects of various phenomena in materials science, geology, biology, tribology and nanot
225 ing of cell biology and its integration with materials science has led to technological innovations i
226 ogress made in chemistry, nanotechnology and materials science has started to impact immuno-oncology,
227 articular at its interfaces with biology and materials science, has been recently established through
228 em, empowered by advances in electronics and materials science, has transformed neuroscience and is i
230 iocompatibility make it of great interest to materials science; however, precise control of its biosy
231 mation provided by this technique has guided materials science in tailoring the synthesis of nanomate
232 ibilities for probing intriguing physics and materials science in the 2D limit as well as enabling un
234 y describe central problems in chemistry and materials science, in areas of electronic structure, qua
235 ical properties are of central importance to materials sciences, in particular if they depend on exte
236 many length scales in various disciplines of materials science including electronic devices, environm
237 ous in biological systems and widely used in materials science, including for the formulation of drug
238 However, the recent surge in two-dimensional materials science is accompanied by equally great challe
240 he utility of this photochemical ligation in materials science is demonstrated by the fabrication of
241 cer biology, immunology, bioengineering, and materials science is important to further enhance the th
245 strategies from environmental chemistry and materials science is therefore essential to provide a re
253 to the study of many fundamental problems in materials science, nanoscience, condensed matter physics
254 However, many samples in physics, chemistry, materials science, nanoscience, geology, and biology are
255 s expected to find important applications in materials science, nanoscience, physics, chemistry and b
256 known as gelation, is central to biophysics, materials science, nanotechnology, and food and cosmetic
257 ost recent applications, now spanning across materials science, nanotechnology, biology, medicine, ge
259 tion in fields such as chemical engineering, materials science, or pharmaceutical and life science.
260 of photoprotecting groups can be applied in materials science, organic synthesis and biological syst
261 loping IONPs as a T(1) contrast agent from a materials science perspective are presented, and how eac
262 Organofluorine chemistry plays a key role in materials science, pharmaceuticals, agrochemicals, and m
264 ave essential roles in catalysis, synthesis, materials science, photophysics and bioinorganic chemist
265 ds is expected to find broad applications in materials science, physics, chemistry and nanoscience.
267 fundamental challenge, hindering progress in materials science, porous media, and biomedical imaging.
268 sful application of this method to exploring materials science problems using x-ray scattering measur
270 r experiencing high velocity collisions, but materials science regarding the extreme events has been
271 g of cellulose crystals, termed texturing in materials science, represents a previously unreported me
272 opment of organic solids for applications in materials science requires a fundamental understanding o
273 nterest in pharmaceutical, agrochemical, and materials science research, due to their unique physical
277 erpretability of machine-learning results in materials science, specifically materials' functionaliti
278 ography is applicable to both biological and materials science specimens, and may be useful for under
279 rstand fundamental questions of relevance to materials science, such as how the size and shape of art
281 elds, including synthetic organic chemistry, materials science, targeted drug delivery and the probin
282 e insights across biological, geological and materials science that are impossible using either indiv
283 he "blue fog," are among the rising stars in materials science that can potentially be used to develo
284 applications in both medicinal chemistry and materials science, there have been limited reports on th
285 pments in communications, nanotechnology and materials sciences, there has been extraordinary growth
287 een applied in various fields of study, from materials science to biological imaging, exploiting the
291 oxicity are introduced, and opportunities in materials science to drive this interdisciplinary field
293 number of fields ranging from biological and materials sciences to catalysis, nanofluidics and geoche
294 search fields such as chemistry, physics, or materials science, to mention a few, arguably as no othe
295 s, novel perspectives have been opened up to materials science towards the development of dynamic mat
296 amily Department of Chemical Engineering and Materials Science, University of Southern California, Lo
297 proposed, being highly challenging from the materials science viewpoint and with the golden thread o
298 sis of thin films is a desideratum of modern materials science where a material's properties depend s
299 by combining advances in nanotechnology and materials science with CL, new avenues for basic and app
300 ool for studies of interfaces in biology and materials science with notable utility in biophysical an