ライフサイエンスコーパス: microelectronics

1 estone in the application of 2D materials to microelectronics.

2 gy, are promising candidates for contacts in microelectronics.

3 tom Probe Tomography and failure analysis of microelectronics.

4 e specifically for materials of relevance to microelectronics.

5 plications including catalysis, sensing, and microelectronics.

6 onstructing quantum platforms and post-Moore microelectronics.

7 ating protection and recycling waste heat of microelectronics.

8 ve implantation of leadless and battery-free microelectronics.

9 g, but not limited to, biomedical, MEMS, and microelectronics.

10 ad spectrum of applications in aerospace and microelectronics.

11 transformative potential for next-generation microelectronics.

12 defects has led to extraordinary advances in microelectronics.

13 gration of electrochemical energy storage in microelectronics.

14 olecular electronic junctions of interest to microelectronics.

15 umber of fields, ranging from biomedicine to microelectronics.

16 n of MOFs as an integral part of solid-state microelectronics.

17 development of silicon-based solar cells and microelectronics.

18 enges in current interconnect technology for microelectronics.

19 ated circuits ignited explosive expansion of microelectronics.

20 nt, such as in nanopatterning technology and microelectronics.

21 or general integration of nanophotonics with microelectronics.

22 rators for powering mobile and even personal microelectronics.

23 elds ranging from separation technologies to microelectronics.

24 ocapacitors, and nanoresistors, analogous to microelectronics.

25 n of PCR-based in vitro biotechnologies with microelectronics.

26 a well-developed science and technology for microelectronics.

27 lds of catalysis, separation technology, and microelectronics.

28 ctly with other technologies such as silicon microelectronics.

29 rfaces based on silicon play in conventional microelectronics.

30 dapting photolithographic techniques used in microelectronics.

31 simple translation of genetic information to microelectronics.

32 ots(9,10), rigid modules containing Si-based microelectronics(11,12) and protective encapsulation mod

33 anular systems(8,9), self-assembly(5,10,11), microelectronics(12,13) and abrasives(14).

34 L could be used at scale for applications in microelectronics(2), biomedicine(3), quantum technology(

35 ons following processes used in conventional microelectronics(29).

36 is crucial in geology, nuclear engineering, microelectronics, among other fields.

37 to a conductivity-tunable building block for microelectronics and biological sensors.

38 ofabrication methodologies that help connect microelectronics and biological systems and yield new ap

39 vel biomechatronic platforms with associated microelectronics and customized software that extract ce

40 Next-generation microelectronics and electrical power systems call for h

41 industry by enabling (stereo)lithography for microelectronics and emergent 3D printing technologies.

42 Modern microelectronics and emerging technologies such as weara

43 recipitation to address global challenges in microelectronics and environmental monitoring, concludin

44 towards scalable optoelectronic systems for microelectronics and information science.

45 separation technologies, detection systems, microelectronics and information technology, and will in

46 Silicon is an excellent material for microelectronics and integrated photonics1-3 with untapp

47 y, although ubiquitous in the fabrication of microelectronics and microelectromechanical systems, is

48 icroscale systems - including microfluidics, microelectronics and microscaffolds - are now being adap

49 ergy storage devices for emerging autonomous microelectronics and microsystems(2-5).

50 in, laminar metal films on oxides for use in microelectronics and other technologies where nanostruct

51 ificial atoms into the world's most advanced microelectronics and photonics platform.

52 r flexibility as switchable knobs for use in microelectronics and quantum applications.

53 n offers opportunities to apply the power of microelectronics and real-time data analytics to chemica

54 plications for emerging fields such as smart microelectronics and soft microrobotics.

55 for the development of functional devices in microelectronics and telecommunication.

56 pation is critical to the scaling of current microelectronics and to the development of novel devices

57 in microdevices for new energy applications, microelectronics, and biomedicine.

58 fiers, catalysts, semiconductors, cosmetics, microelectronics, and drug carriers.

59 photoimaging devices), low cost/large format microelectronics, and in biological imaging and biosenso

60 fields of catalysis, separation, adsorption, microelectronics, and medical diagnosis.

61 often associated with materials fabrication, microelectronics, and microfluidics.

62 conductivity in fields of energy materials, microelectronics, and nanoscale heat transfer.

63 ty of potential applications in biomedicine, microelectronics, and optics.

64 Affordable and readily available microelectronics are becoming prevalent in teaching labo

65 tforms with dedicated operating software and microelectronics are designed, modeled, nanofabricated,

66 Semiconductor microelectronics are emerging as a powerful tool for bui

67 Limited by the size of microelectronics, as well as the space of electrical veh

68 opens promising avenues for next-generation microelectronics, atomic-scale imaging, and catalysis.

69 s have the potential to revolutionize modern microelectronics because they are easily integrated with

70 As consumer microelectronics become ever more ubiquitous, there are

71 nium alloys are technologically important in microelectronics but also they are an important paradigm

72 in devices for memory storage and integrated microelectronics, but progress has long been hampered by

73 nherent ability to self-assemble, biomimetic microelectronics can firmly yet gently attach to an inor

74 ure across diverse fields like nanomedicine, microelectronics, catalysis, and plasmonics.

75 opalladates (POPs), where Pd is critical for microelectronics, catalysts, and drug production.

76 or applications including energy conversion, microelectronics, chemical and biological sensing, and b

77 nd applications, like low-k buffer layers in microelectronics, chiral catalysts, chromatographic supp

78 The long spin coherence time and microelectronics compatibility of Si makes it an attract

79 emission area fabricated in an open-foundry microelectronics complementary metal-oxide-semiconductor

80 A method to produce soft and stretchable microelectronics composed of a liquid-phase Gallium-Indi

81 evices to be used in catalysis, spintronics, microelectronics, data storages and bio-applications.

82 mechanisms of energy-conversion systems and microelectronics devices.

83 uously decreasing size of device features in microelectronics draws growing attention to the structur

84 n has persevered as the primary substrate of microelectronics during last decades.

85 n the backbone of the newest developments in microelectronics, energy conversion, sensing device desi

86 roperties that render them integral parts in microelectronics, energy storage devices, and chemical s

87 portant to sustain the global consumption of microelectronics, energy, and pharmaceuticals.

88 t component in silicon device processing for microelectronics, energy, and sensor applications.

89 providing considerable potential utility in microelectronics fabrication methods.

90 the biomedical, coatings, microfluidics and microelectronics fields.

91 s (ONNs) promise computing efficiency beyond microelectronics for modern artificial intelligence (AI)

92 , we design optical devices using a standard microelectronics foundry process that is used for modern

93 ults benefit most areas such as geosciences, microelectronics, glass industry, and ceramic materials.

94 ir deployment in commercial-scale devices in microelectronics hardware.

95 Flexible microelectronics has shown tremendous promise in a broad

96 nergetic interaction among biotechnology and microelectronics have advocated the biosensor technology

97 Fifty years of Moore's law scaling in microelectronics have brought remarkable opportunities f

98 ose that cannot be addressed by conventional microelectronics in rigid materials and constructions.

99 The rise of microelectronics in the 1970s and 1980s resulted in huge

100 d quantum dots and the transistors in modern microelectronics--in fabrication methods, physical struc

101 adapts the lithographic techniques from the microelectronics industry and marries these with the rol

102 ion imaging materials and processes from the microelectronics industry for the fabrication of DNA pro

103 ceramic capillary tips generally used in the microelectronics industry for the production of DNA micr

104 The microelectronics industry is pushing the fundamental lim

105 The silicon-based microelectronics industry is rapidly approaching a point

106 imilar to the way silicon revolutionized the microelectronics industry, the proper materials can grea

107 SiO2 would be of significant interest to the microelectronics industry.

108 stablished as the material of choice for the microelectronics industry.

109 onsumption and variability issues in today's microelectronics industry.

110 an the dominant material in the conventional microelectronics industry: it also has potential as a ho

111 tions, such as targeted delivery, catalysis, microelectronics, integrated metamaterials and tissue en

112 ical mismatch between tissue and implantable microelectronics is essential for reducing immune respon

113 soft actuators with the imperceptibility of microelectronics, is introduced.

114 wer, speed and volatility considerations for microelectronics may no longer exist.

115 with potential applications in the field of microelectronics, medicine, environment, and industry.

116 hnologies, such as computer storage devices, microelectronics, microdynamic systems, and photonics, m

117 Advances in microelectronics, microfluidics, polymers and microfabri

118 an artificial pancreas by combining advanced microelectronics, nanotechnology and advanced biomateria

119 Integration in microelectronics of such crystalline waveguides requires

120 ntennas, resonators and phase shifters--with microelectronics offers tantalizing device possibilities

121 optical devices that are integrated with the microelectronics on chips.

122 Across the fields of magnetism, microelectronics, optics, and others, engineered local v

123 chnologies in a wide range of fields such as microelectronics, optoelectronics, and energy storage.

124 ne learning for a variety of applications in microelectronics, optoelectronics, photonics, and energy

125 understanding ionic charge carrier motion in microelectronics or nanoscale material systems.

126 e sensors (5 mm x 5 mm x 250 mum) require no microelectronics or power at the sensing node and can be

127 of appropriate material such as silicon for microelectronics or superalloys for turbine blades.

128 s attention for application in areas such as microelectronics, organic batteries, optics, and catalys

129 , and is important in many processes used by microelectronics, pharmaceutical, food and other industr

130 as trench insulation between transistors in microelectronics, planar waveguides, microelectromechani

131 sensitivity while also being compatible with microelectronics processing technologies.

132 prepared using scalable photolithography and microelectronics processing.

133 The development of microelectronics prompts a search for precursors that ca

134 s now, silicon has been the workhorse of the microelectronics revolution and a key enabler of the inf

135 reaching its limits, threatening to end the microelectronics revolution.

136 n as a dry conductive reversible adhesive in microelectronics, robotics, and space applications.

137 The biotechnology, microelectronics, software, instrumentation, pharmaceuti

138 are challenging to process using traditional microelectronics techniques.

139 Advancement in microelectronics technology enables autonomous edge comp

140 er to leverage the infrastructure of silicon microelectronics technology for the fabrication of optoe

141 radiation hardness has reached consensus in microelectronics, the size-performance balance for their

142 As is the case for silicon-based microelectronics, the use of complementary logic element

143 aging method, which is generally utilized in microelectronics thermal imaging applications.

144 on volts) makes cBN a promising material for microelectronics thermal management, high-power electron

145 In silicon-based microelectronics, these are achieved through the use of

146 f electronic devices, particularly in scaled microelectronics, they have proven beneficial in numerou

147 hold promise for applications spanning from microelectronics to catalysis.

148 s vital for progress in diverse fields, from microelectronics to energy storage.

149 ribute to developments in areas ranging from microelectronics to medical diagnosis.

150 g from the fabrication of silicon wafers for microelectronics to the determination of protein structu

151 Silicon underpins nearly all microelectronics today and will continue to do so for so

152 In conventional digital microelectronics, two-dimensional shift registers are ro

153 on can be transmitted to cells directly from microelectronics via electrode-activated redox mediators

154 ins a challenge in radio-frequency and power microelectronics, where they perform vital energy transd

155 mands on device fabrication: next-generation microelectronics will need minimum features of less than

156 y demonstrate a fully biocompatible wireless microelectronics with a self-assembled design that can b

157 a nearly ideal substrate for integration of microelectronics with biological modification and sensin

158 ectrically conductive hydrogel-based elastic microelectronics with Young's modulus values in the kilo

159 o stimulate the next steps towards MOF-based microelectronics within the community.