コーパス検索結果 (1語後でソート)
通し番号をクリックするとPubMedの該当ページを表示します
1 ree devices for electric-write magnetic-read data storage.
2 ses, imaging techniques, data processing and data storage.
3 ion, as is required to support combinatorial data storage.
4 d extensively for applications in memory and data storage.
5 of 500 Hz, initially averaged to 100 Hz for data storage.
6 ng and easy parsing, graphical rendering and data storage.
7 as catalysis and ultra-high-density magnetic data storage.
8 f their microarray data from the location of data storage.
9 biomedical imaging, optical lithography and data storage.
10 of microscopy, photolithography, and optical data storage.
11 es that integrate information processing and data storage.
12 including catalysis, optics, biosensing and data storage.
13 d computer-assisted analysis, reporting, and data storage.
14 ns for achieving rapid, large-scale archival data storage.
15 t media has been a major obstacle in optical data storage.
16 from biosensing and catalysis to optics and data storage.
17 ineered systems for biological computing and data storage.
18 improvement has been realized in volumetric data storage.
19 aphic imaging, and three-dimensional optical data storage.
20 g guest-host reflective LCDs and holographic data storage.
21 useful in many technologies from sensing to data storage.
22 unprecedented levels of security in genomic data storage.
23 l for low-power, high-density and high-speed data storage.
24 well as transducers for high-density optical data storage.
25 nsing, molecular computers, and high-density data storage.
26 imate scaling alternative for future digital data storage.
27 application for low power ultra high-density data storage.
28 th each other, are good candidates for dense data storage.
29 ocesses such as two-photon 3D patterning and data storage.
30 cations in organic photovoltaics and optical data storage.
31 ortant due to their manifold applications in data storage.
32 devices, solar energy conversion and optical data storage.
34 to charge trapping in the nanoparticles for data storage and a tunnelling process in the high conduc
37 ence data generated grows, new paradigms for data storage and analysis are increasingly important.
38 ccess to up-to-date resources for microarray data storage and analysis, combined with integrated tool
41 e interest in the context of next-generation data storage and communication devices, opening avenues
45 sible methods for high-density, charge-based data storage and for high-resolution charge-based printi
46 ss of phase-change materials in the field of data storage and functional systems stems from their dis
49 ures, computational resource management, and data storage and integration in the context of recent de
51 object model will greatly aid in integrating data storage and management, and facilitate reuse of sof
52 ge gaps in knowledge, technology, computing, data storage and manipulation, and systems-level integra
54 he application of phase-change materials for data storage and memory devices takes advantage of the f
56 nowires make them desirable for high-density data storage and other magnetic-device applications.
57 ing to applications ranging from holographic data storage and photoalignment to photoactuation and na
58 rerequisite for exploiting spins for quantum data storage and processing is long spin coherence times
59 Magnetic and spin-based technologies for data storage and processing provide unique challenges fo
64 Ms) are promising candidates for nonvolatile data storage and reconfigurable electronics, but high pr
66 nomic-scale data acquisition and validation, data storage and retrieval, and data analysis, indexed a
67 is generation, personal workbench spaces for data storage and sharing, and active user community supp
70 ch of novel, improved materials for magnetic data storage and spintronic devices, compounds that allo
72 s for potential applications such as optical data storage and switching and biological fluorescent la
79 f the system range from sequence analysis to data storage and visualization and installations exist a
82 PiiMS) provides integrated workflow control, data storage, and analysis to facilitate high-throughput
83 tive use of ferroelectric nanostructures for data storage, and are of fundamental value for the theor
85 tions such as microscopy, display, security, data storage, and information processing.Realizing metas
86 al connectivity between layers of computing, data storage, and input and output (in this instance, se
90 magnetic memory effect and a prerequisite of data storage-and so far lanthanide examples have exhibit
91 tabase and web application that supports the data storage, annotation, analysis and information excha
92 ic multiplexing and multidimensional optical data storages, anti-counterfeiting, and optical encrypti
93 erred over in-plane magnets for high-density data storage applications due to their significantly lar
94 targeted both fundamentally and for expanded data storage applications, when antagonistic interaction
95 ing collective spin-vortices of relevance to data storage applications-are realized in the structural
96 ling constants thus obtained are invalid for data-storage applications, where the more difficult to a
98 ons in neuromorphic computing and multilevel data storage, as well as applications that require contr
99 sensing, nonlinear optics, ultrahigh-density data storage, as well as plasmonic metamaterials and met
100 These experiments suggest a path towards data storage at the atomic limit, but the way in which i
102 d allow for realization of various photonic, data storage, biomedical and optoelectronic applications
103 exciting potential in biomedical sciences as data storage can be coupled to sensing of biological mol
105 mpowered by advances in computational power, data storage capability, and improved sensor technology
106 e infrared motion detector, microcontroller, data storage card, and batteries mounted in a small plas
109 -seq experiments has significantly increased data storage costs and communication bandwidth requireme
111 ple, combines remarkable longevity with high data storage densities and has been demonstrated as a me
116 omising alternatives for the next-generation data storage devices due to their high flexibility, thre
117 s have possible applications in spintronics, data storage devices, chemical sensors, building blocks
118 as photonic materials, high-density magnetic data storage devices, microchip reactors and biosensors.
124 tability and suitability for use in magnetic data-storage devices, can be modified by varying the exc
125 ortant role in their applications in optical data storage, document security, diagnostics, and therap
127 asma separation, flow monitoring, timing and data storage enable multiple devices to be run simultane
128 oelectrics and as phase-change materials for data storage, even 22-kHz magic-angle spinning cannot re
129 ficient digital logic circuits and for dense data storage-fabricated on vertically stacked layers in
130 modules, and to the emerging common sequence data storage format of the Open Bioinformatics Database
132 In addition to serving as a centralized data storage hub, GEO offers many tools and features tha
134 t, with judicious molecular design, magnetic data storage in single molecules at temperatures above l
135 materials, has revolutionized the media and data storage industries by providing inexpensive, high-s
140 R) materials in applications such as optical data storage is generally limited by the concentration o
141 Ms) may be used as the smallest component of data storage, is the size of the barrier to reversal of
142 for their potential in subwavelength optics, data storage, light generation, microscopy and bio-photo
145 been commercialized as optically rewritable data-storage media, and intensive effort is now focused
146 h genetic material itself provides a natural data storage medium, tools that allow researchers to rel
147 sions that allow the underlying taxonomy and data storage models to be maintained and updated with ea
149 of these plates hold promise for near-field data storage, noncontact sensing, imaging, and nanolitho
151 applications, such as molecular electronics, data storage, optoelectronics, displays, sacrificial tem
153 ndamentally new capabilities to bio-sensing, data storage, photolithography and optical communication
155 tive data access operations while minimizing data storage requirements and are critical enablers of r
156 e, and as biological knowledge advances, the data storage requirements and types of queries needed ma
159 computing (HPC) virtual system, iPlant cloud data storage resources and Pegasus workflow management s
160 ing costs dropping <$1000 for human genomes, data storage, retrieval and analysis are the major bottl
163 echnology enabling light modulators, optical data storage, sensors and numerous spectroscopic techniq
165 cs and optics and may enable applications in data storage, singular optics, displays, electro-optic d
167 ncreasingly serious concern, yet no standard data storage solutions exist that enable compression, en
168 magnets because of potential applications in data storage, spintronics, quantum computing, and magnet
169 genome is best modelled as a read-write (RW) data storage system rather than a read-only memory (ROM)
170 tile readout in a digital volume holographic data storage system that uses a pair of mutually incoher
171 sents the only known random access DNA-based data storage system that uses error-prone nanopore seque
172 e female edible crabs tagged with electronic data storage tags (DSTs), we demonstrate predominantly w
174 est in three-dimensional laser-based optical data storage techniques, which can potentially provide e
175 met by isolated improvements in transistors, data storage technologies or integrated circuit architec
180 nd promises unprecedented speed for magnetic data storage that is three orders of magnitudes faster t
182 of their promising applications ranging from data storage to biological imaging and drug delivery.
184 or data access and input/output routines for data storage, together with accompanying documentation.
185 near-field scanning microscopy, holographic data storage, tunable plasmonic tweezers, and integrated
190 ns, optical sensing and imaging, and optical data storage with extreme spatial confinement, broad ban
191 It consists of a relational database for data storage with many user-interfaces for data manipula
WebLSDに未収録の専門用語(用法)は "新規対訳" から投稿できます。