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1 evelopment, and nucleic acid based biosensor device design.
2 the electric fields and fluid flow to guide device design.
3 mbrane, and the implications for biology and device design.
4 perties via substrate engineering for future device design.
5 e-scale high-quality vertical light emitting device design.
6 unction width, providing guidance for future device design.
7 inclusion of an acoustic transition layer in device design.
8 in recent times has opened up new avenues in device design.
9 this is due to inadequate training, or poor device design.
10 h electromagnetic solvers for optomechanical device design.
11 iscuss future prospects for QD materials and device design.
12 s with important implications in stretchable device design.
13 de the groundwork for future improvements in device design.
14 ation, and define engineering guidelines for device design.
15 ncertainty regarding its energy has hindered device design.
16 s apply to nanoelectronics and semiconductor device design.
17 et operations can be achieved using the same device design.
18 c devices, as well as providing guidance for device design.
19 arrier relaxation times required for optimum device design.
20 0 particles per second using the simplest of device designs.
21 raphene heterostructure and strain-releasing device designs.
22 d ionic transport, and will enable new ionic device designs.
23 ay open up new opportunities for spintronics device designs.
24 s that could be exploited in novel nanoscale device designs.
25 though nearly all work has focused on planar device designs.
27 ess energy, and the simpler and more compact device design allows direct integration into PEMFC stack
32 e complexity associated with experimental or device design and requires substantial labor for impleme
33 ed in contemporary fuel cells severely limit device design and restrict catalyst choice, but are esse
35 toPAD-developed to quickly create and modify device designs and provide a free alternative to commerc
37 analysis was performed to compare different device designs and was verified with flow modeling to op
38 along with microscopic sizes, can influence device design, and give examples from our own work using
39 microelectronics, energy conversion, sensing device design, and many other fields of science and tech
40 esults should lead to more reliable graphene device design, and provide a framework to interpret expe
41 viability and function, its relationship to device design, and the role of, and factors affecting, o
44 interesting results that are informative to device design as well as experimental data interpretatio
45 dual skyrmions controllably in an integrated device design at a selected position has been reported y
46 rol ripple structure in graphene could allow device design based on local strain and selective bandga
49 s motivated the search for new materials and device designs capable of splitting water using only ene
50 ate materials will ensure that future fusion devices design components with optimal thermal strength.
52 rtance of material selection in microfluidic device design, especially in applications involving drug
55 Challenges remain, not least encouraging device design focused on smaller infants and the inevita
58 development of a microcuvette: a specialized device designed for exposing cell cultures to intense PE
59 e, to a jet-stirred reactor, an experimental device designed for the study of low-temperature combust
61 ul in the study of more advanced nanofluidic device designs for tailoring ionic current rectification
63 of U.S. Food and Drug Administration-cleared devices designed for indocyanine green-based perfusion i
67 ritical care setting; mechanical circulatory devices designed for pediatric patients; and surgery in
68 Given the recent interest in paper-based devices designed for quantitative analysis in point-of-c
70 In vitro testing revealed that the initial device design had detection limits for amino acids of ap
71 ical experiments, but open-source sharing of device designs has lagged behind sharing of other resour
73 nd hydrodynamics predict animal movement and device design in air and water through the computation o
74 in engineering has been a critical aspect of device design in semiconductor manufacturing for the pas
77 uming motions with a single-channel pipet or device designs limited to the configurations of traditio
78 frequent type of revision, changes involving device design (n = 667; 24%) and labeling (n = 417; 15%)
81 e structures, but the kink configuration and device design places limits on the probe size and the po
83 , single-group trial of a ventricular assist device designed specifically for children as a bridge to
84 an implantable mixed-flow ventricular assist device designed specifically for patients up to 2 years
86 mental understanding of these materials, for device design, stability studies, and quality control be
87 tegies for forming partnerships, prototyping devices, designing studies, and evaluating POC diagnosti
90 intronic circuits with a versatile, scalable device design that is adaptable to emerging material phy
92 ding manufacturing changes that do not alter device design, the number of supplements approved each y
97 of the proposed soft materials and ultrathin device designs through theoretical modeling and finite e
98 or material choice, material properties, and device design to achieve low-loss PS-BAW resonators alon
99 es, and underline the importance of holistic device design to achieve the intrinsic performance limit
100 illness was detected after in-home use of a device designed to be highly effective in removing micro
102 scribe a simple, easy-to-fabricate perfusion device designed to focally deliver pharmacological agent
103 ichia coli cells by employing a microfluidic device designed to follow steady-state growth and divisi
104 f a transesophageal echocardiographic-guided device designed to implant artificial expanded polytetra
105 The Helex septal occluder is a new type of device designed to improve the results of transcatheter
109 o characterization pipeline for prescreening device designs to identify promising candidates for in v
111 nal mechanical cardiopulmonary resuscitation devices designed to augment circulation, and may soon ad
112 analyte species in nanoscale cantilever-type devices designed to detect small concentrations of biomo
113 IVD have been confined to purely mechanical devices designed to either eliminate or enable flexibili
115 ontrol signals for neuroprosthetic assistive devices designed to interact with objects in a flexible
116 s assumption through the use of microfluidic devices designed to mimic human capillary constrictions
117 e surface modification of glass microfluidic devices designed to perform electrophoretic separations
119 ally used in reference to sensory prosthetic devices designed to replace input from one defective mod
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