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1 ing for biomedical applications and wearable electronics).
2 in applications of flexible and stretchable electronics.
3 ctor promises interesting applications in 2D electronics.
4 ing a noncovalent method of tuning fullerene electronics.
5 ployed as a protective layer for implantable electronics.
6 ns of horizontal 2D MoS2 in electronics/opto-electronics.
7 xanes to function as molecular insulators in electronics.
8 can be monitored continuously with standard electronics.
9 as well as presence and age of furniture and electronics.
10 interactions between biological species and electronics.
11 ally used as an energy solution for wearable electronics.
12 -generation ultrathin, low-power, high-speed electronics.
13 es without prior knowledge of programming or electronics.
14 reless and self-powered sensors or low-power electronics.
15 y to the realisation of high-yield low-power electronics.
16 iocompatible, and ultralightweight transient electronics.
17 ty of AlN TRRAM for future transparent harsh electronics.
18 permeable membrane substrates for epidermal electronics.
19 king analog GKTFET potentially useful for RF electronics.
20 applications ranging from catalysis to novel electronics.
21 ith various form-factor designs for wearable electronics.
22 rmation provides a novel paradigm for future electronics.
23 al processing is a major challenge in modern electronics.
24 easibility of optically defined, transparent electronics.
25 tion to test the radiation hardness of space electronics.
26 or economical manufacturing of bioresorbable electronics.
27 y transparent hold unique promise for future electronics.
28 s paving new pathways toward atomically thin electronics.
29 vel electrochemical concepts in future oxide electronics.
30 tions that vastly exceed the capabilities of electronics.
31 to various electrodes for portable/wearable electronics.
32 f its potential use in materials for organic electronics.
33 c, air-stable, pentagonal 2D material for 2D electronics.
34 eration of wearable energy devices in modern electronics.
35 reat potential in smart textiles or wearable electronics.
36 e role in the development of next generation electronics.
37 tions in next-generation wearable functional electronics.
38 fields, ranging from composites to flexible electronics.
39 ous studies which have focused on automotive electronics.
40 es for applications in flexible and wearable electronics.
41 ce of intrachain charge transport in plastic electronics.
42 layered semiconductor of interest for valley electronics.
43 gh energy density are demanded for conformal electronics.
44 oses but also for cosmetics, agriculture and electronics.
45 apability are attractive for modern wearable electronics.
46 to fit the properties required in deformable electronics.
47 ticles as well as their potential for future electronics.
48 applications at the interface of biology and electronics.
49 ted systems, wearable devices and bio-sensor electronics.
50 es for globally deformable yet locally stiff electronics.
51 a mono-layer transition metal dichalcogenide electronics.
52 r novel high-speed low-power superconducting electronics.
53 d be highly beneficial for powering wearable electronics.
54 optical interconnects for silicon integrated electronics.
55 pment of organic photovoltaics and molecular electronics.
56 mperature process is very suitable for paper electronics.
57 sciences, and most importantly computers and electronics.
58 h-resolution displays and human-centric soft electronics.
59 the harvesting of solar energy and molecular electronics.
60 transistors in next generation semiconductor electronics.
61 nhancement and advance thermal management in electronics.
62 ations of 1-20 nm organic films in molecular electronics.
63 hly expected for soft tissue repair and soft electronics.
64 their application in wearable or stretchable electronics.
65 sue engineering, soft robotics, and wearable electronics.
66 tance for realizing tunable energy efficient electronics.
67 trate, enabling more complex low-dimensional electronics.
68 vices for next-generation wearable, portable electronics.
69 zing programmable logic elements in magnetic electronics.
70 sts a viable route for designing destructive electronics.
71 on transport is a generic feature of viscous electronics.
72 al for their practical applications in novel electronics.
73 ely a result of the density of furniture and electronics.
74 local electronic properties in silicon-based electronics.
75 ic transistor that forms the basis of modern electronics.
76 conductors and as active components in power electronics.
77 lications that span biomedicine to molecular electronics.
78 several domains of stretchable and wearable electronics.
79 polymers have great potential in large-area electronics.
80 potentially offer integrability into modern electronics.
81 s inspirations for smart designs in flexible electronics.
82 apacitors (MLCC) are widely used in consumer electronics.
84 in antimony, a component used in batteries, electronics, ammunitions, plastics, and many other indus
87 ies for passive heat exchange in stretchable electronics and bioinspired robotics, which we demonstra
91 chargeable lithium-ion batteries in portable electronics and electric vehicles has spurred intensive
92 ddressing key materials challenges in modern electronics and enables control of dissipation at the na
93 ces could impact areas ranging from wearable electronics and energy harvesting devices to smart prost
94 doping strategies have enabled semiconductor electronics and forging enabled introduction the of iron
96 ght emission, data communication, high-speed electronics and light harvesting (8-16) require a thorou
101 ed microfluidics, instrumented with flexible electronics and optoelectronic sensors in a mechanically
102 re we performed a comprehensive study on the electronics and optoelectronics properties of the AlN/Ga
103 he application of these materials in organic electronics and optoelectronics, the construction of oli
107 rly attractive in the context of non-silicon electronics and photonics, where the ability to re-use t
110 cessing is one of major challenges in modern electronics and spin caloritronics, but not yet well acc
112 te to overcome both the speed limitations of electronics and the critical dimensions of photonics.
113 nal electrophysiology, spatially inefficient electronics and the need for tissue-to-electrode proximi
116 that combines nanomaterials with biology and electronics and, in so doing, offers the potential to ov
118 in materials have great potential for use in electronics, and are thought to make possible the first
119 l greatly exceed the capabilities of current electronics, and are unlikely to be met by isolated impr
121 g and controlling DNA origamis with standard electronics, and enable their use as moving parts in ele
123 eir applications within soft and stretchable electronics, and future opportunities and challenges are
124 ipresence of lithium-ion batteries in mobile electronics, and hybrid and electric vehicles necessitat
125 challenges, here we integrate microfluidics, electronics, and inkjet printing to build an ultra-low-c
126 ing ultrathin films form the basis of modern electronics, and may lead to the scalable fabrication of
131 applications in tissue engineering, flexible electronics, and soft robotics call for approaches that
134 t implications in a broad range of molecular electronics applications from designing robust molecular
137 ensors combined with low-power silicon-based electronics are a viable and efficient approach for medi
139 der development for next-generation wearable electronics are flexible, knittable, and wearable energy
142 lethora of materials employed in the organic electronics area for application in the bioelectronics f
144 o transfer power from outside of the body to electronics at various locations along the GI tract.
146 platform for green, foldable and disposable electronics based on low cost and versatile materials.
153 time-dependent histology studies of the mesh electronics/brain-tissue interface obtained from section
155 do for photonics what semiconductors did for electronics, but the challenge has long been in creating
161 lating electrodes in which the per-electrode electronics consume an area of 25.5 mum by 25.5 mum.
162 combining the paper sensor with conventional electronics, data concerning respiration can be transmit
164 Printed electronics are a burgeoning area in electronics development, but are often stymied by the la
166 spintronic devices in flexible and wearable electronics devices for a plethora of biomedical sensing
167 is donor from the drift layer of Ga2O3 power electronics devices will be key to pushing the limits of
169 the difficulty in powering millimeter-sized electronics devices without using batteries, which compr
173 use of self-assembled monolayers in organic electronics, discuss the mechanism of interaction of SAM
174 cess of the doses needed to damage TMD-based electronics due to defects generated in common dielectri
175 ost promising candidates for next-generation electronics due to their atomic thinness, allowing for f
177 o be potential materials for atomically thin electronics due to their unique electronic and optical p
179 ies to meet the growing demands for portable electronics, electric vehicles and grid-scale energy sto
180 development and clinical testing of a novel electronics enabled microfluidic paper-based analytical
181 und numerous applications in pharmaceutical, electronics, environmental, cosmetics, and hygiene indus
182 ental studies show that the established skin-electronics exhibit superior mechanical enhancements aga
183 ifunctional technologies combing transparent electronics, flexible electronics and thermoelectricity.
184 rent properties of polymers and soft organic electronics for applications at the interface of biology
185 es investigate the functionality of the soft electronics for HCI-enabled swallowing training, which i
186 a promising processing technique in organic electronics for microstructure/charge transport modifica
187 egrated with the next generation stretchable electronics for realizing low-power, stand-alone, self-s
189 cal allows for the physical isolation of the electronics from the human body while enabling efficient
192 the increasing energy consumption in silicon electronics has motivated research into emerging devices
193 ever-growing market of flexible and wearable electronics has nourished progress in building multifunc
196 emands and shorter use lifetimes of consumer electronics have resulted in the rapid growth of electro
198 iles with potential applications in wearable electronics, home security, and personalized healthcare.
199 ocused on chemicals applied to furniture and electronics; however, camping tents sold in the United S
200 We recently reported ultraflexible open mesh electronics implanted into rodent brains by syringe inje
201 trates clinical feasibility of the ergonomic electronics in HCI-driven rehabilitation for patients wi
202 current interest for a variety of low power electronics in which the magnetic state is used either f
203 ium-ion batteries are ubiquitous in portable electronics, increased charge rate and discharge power a
204 ential for representing a paradigm change in electronics, information processing and unconventional c
209 complex nanofluidic systems with integrated electronics is essential to realizing ubiquitous, compac
211 such, the radiation stability of WSe2-based electronics is not expected to be limited by the radiati
212 nge to the deployment of such gastroresident electronics is the difficulty in powering millimeter-siz
214 ulation for sensitive components in flexible electronics.Minerals are rarely explored as building blo
215 ar monolayers, which is central to molecular electronics (MolEl), using large-area junctions (NmJ).
216 nce of novel applications such as catalysis, electronics, nanomaterial synthesis and biosensing.
217 nefit significantly from lightweight organic electronics, now spanning from displays to logics, becau
219 ination is controlled by the solvent and the electronics of the cyclopentadienyl (Cp(x)) ligand on Ir
220 regioisomers has been dictated by the innate electronics of the fluorinated arene, limiting the synth
221 hich is of fundamental interest in molecular electronics, oligo(arylene-ethynylene) (OAE) molecular w
224 y bringing all-transparent, high-power oxide electronics operating at room temperature a step closer
225 conductivity provides a venue for nonlinear electronics, optical applications, and the development o
227 ng of MoS2 to fabricate suitable devices for electronics, optoelectronics, and energy conversion.
228 enum disulfide (MoS2) structures, in various electronics, optoelectronics, and flexible devices requi
229 assemblies and materials for use in optics, electronics, optoelectronics, photonics, magnetic device
230 didates for a broad scope of applications in electronics, optoelectronics, topological devices, and c
231 ting species in areas as relevant as organic electronics or biomedicine has motivated the search for
233 n transistors are at the frontiers of modern electronics owing to their discrete voltage regulated op
234 many measurements in the field of molecular electronics, particularly those measurements based on si
235 of microsystems for numerous applications in electronics, photonics and other areas often requires mi
236 ain slices containing nearly the entire mesh electronics probe showed that the tissue interface was u
237 antation achieved by ultraflexible open mesh electronics probes provide substantial advantages and co
238 scalable scheme for highly multiplexed mesh electronics probes to bridge the gap between scalability
240 future synthetic targets for single-molecule electronics, qualitative design rules are needed, which
241 Most of the magnetic devices in advanced electronics rely on the exchange bias effect, a magnetic
243 ng elastomers, plastics, hydrogels, flexible electronics, resins, engineering polymers and composites
244 nanophotonics, towards establishing an opto-electronics roadmap, akin to the International Technolog
245 have many potential applications in wearable electronics, robotics, health monitoring, and more.
246 f electronics (e.g., wearable or implantable electronics, sensors for soft robotics, e-skin) must ope
249 ded in a compact system comprising dedicated electronics, shielding, and pumping unit controlled by c
250 ar and parallel brain slices containing mesh electronics showed that the distribution of astrocytes,
251 t may find potential application in wearable electronics, soft robotics, and biomedical devices.
252 ng phenomena that underlie conventional spin electronics (spintronics), and provides a mechanism for
254 al fabrication method in areas as diverse as electronics, structural materials, tissue engineering, a
255 ently as a promising option for use in power electronics such as thermoelectric and piezoelectric gen
256 offers new opportunities in next-generation electronics, such as augmented reality devices, smart su
257 microglia are nearly the same from the mesh electronics surface to the baseline far from the probes,
259 tractive for applications in a wide range of electronics systems that desire ultralow power operation
260 iointegration of various sensors in wearable electronics systems, and toward advanced bionic skin app
262 printing is a new method for producing soft electronics that combines direct ink writing of conducti
263 ation of the network structure of automotive electronics that enables a comprehensive quantification
264 olymer transistors for solution-based analog electronics that meets performance and power-dissipation
265 pintronics is an alternative to conventional electronics that offers devices with high performance, l
266 devices pave the way for a new generation of electronics that will change the way we see and interact
267 Advances in wireless technologies, low-power electronics, the internet of things, and in the domain o
269 e device size and integrate it with wearable electronics, there is an urgent requirement of realizing
270 reate geometries potentially useful for opto-electronics, thermoelectrics, and quantum computing.
273 ented here open up the potential of consumer electronics to cut lengthy test waiting times, giving pa
276 e fact through the increasing application of electronics to interface with human neurons in the limbs
277 tectural choices that combine photonics with electronics to optimize performance, power, footprint, a
279 ations in industry, healthcare, and consumer electronics, to emerging product categories of high pote
281 significant expansion of the single-molecule electronics "tool-box" for the design of junctions with
282 first step in integrating biology with nano-electronics towards realizing fully self-assembled biona
283 ology is of critical importance for portable electronics, transportation and large-scale energy stora
284 are widely used, e.g. as casings of consumer electronics (TVs, computers, routers, etc.), which are p
285 e field of energy, to the area of large-area electronics using MHPs as the semiconductor material.
286 ighly efficient low-power analog and digital electronics using ZnO and/or other semiconducting nanoma
287 limited counting rate imposed by the readout electronics, we show that both core-loss and low-loss sp
288 e received increasing attention in robotics, electronics, wearable, and healthcare applications.
289 gated radical polymers in energy storage and electronics, where careful attention to the redox potent
291 such as electrochemistry, catalysis, and SM electronics, which all benefit from the vibrational char
295 st solution for high performance stretchable electronics with broad applications in industry, healthc
297 storage calls for the development of modern electronics with multiple stacking architectures that in
298 crystal thin films and fabricating flexible electronics with these conventionally rigid materials.
300 and opportunities in the area of MHPs-based electronics, with particular emphasis on manufacturing,
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