ライフサイエンスコーパス: information science

1 s in optoelectronics, catalysis, and quantum information science.

2 e emergent electronic properties for quantum information science.

3 chiral molecules for applications in quantum information science.

4 ers would enable new applications in quantum information science.

5 s ranging from spintronic devices to quantum information science.

6 lications in molecular magnetism and quantum information science.

7 coherence is a key goal of molecular quantum information science.

8 imitation on the growth of molecular quantum information science.

9 g platforms for magnetic sensing and quantum information science.

10 oelectronic systems for microelectronics and information science.

11 diodes, photodetectors, lasers, and quantum information science.

12 iple dimensions that are crucial for quantum information science.

13 driven by potential applications in quantum information science.

14 mising to enable new applications in quantum information science.

15 for applications in spintronics and quantum information science.

16 be potentially leveraged for use in quantum information science.

17 al materials are of key interest for quantum information science.

18 d problems is a central challenge in quantum information science.

19 idelity qubits is a key challenge in quantum information science.

20 in spintronics, magnetic memory, and quantum information science.

21 ems in harnessing the power of complexity in information science.

22 phenomena intrinsic to the field of quantum information science.

23 rich material platform for advancing quantum information science.

24 he complexity of classical inseparability in information science.

25 spin qubit pairs for applications in quantum information science.

26 ility as a qubit for applications in quantum information science.

27 d enabling potential applications in quantum information science.

28 ptical transitions for metrology and quantum information science.

29 ntal physics and are at the heart of quantum information science.

30 ton generation, quantum sensing, and quantum information science.

31 well as applications in sensing and quantum information science.

32 r optomechanical quantum control and quantum information science.

33 system is a key capability in modern quantum information science.

34 ties to exploit QDs as platforms for quantum information science.

35 applications ranging from sensing to quantum information science.

36 ng and sensing to quantum optics and quantum information science.

37 ught after as critical components of quantum information science.

38 with multipartite quantum states in quantum information science.

39 or application of quantum cloning in quantum information science.

40 are key elements for applications in quantum information science.

41 g applications in quantum optics and quantum information science.

42 red for a variety of applications of quantum information science.

43 e realisation of many experiments in quantum information science.

44 e of the prime goals in the field of quantum information science.

45 tical ideas and the implications for quantum information science.

46 networks is one of the main goals of quantum information science.

47 em may allow for new applications in quantum information science.

48 w capabilities in quantum optics and quantum information science.

49 mechanics and is a key resource for quantum information science.

50 m may find important applications in quantum information science.

51 ur method for properties critical to quantum information science.

52 he first of these is that epidemiology is an information science.

53 c ensembles, a powerful resource for quantum information science.

54 tific advances in quantum optics and quantum information science.

55 o their potential role as qubits for quantum information science.

56 central challenge in spintronics and quantum information science.

57 h systems also provide test beds for quantum information science.

58 thus we describe a valuable tool for quantum information science.

59 and engendering a new view of biology as an information science.

60 s for accomplishing diverse tasks in quantum information science.

61 herence and has fueled the growth of quantum information science.

62 r insights for molecular sensing and quantum information sciences.

63 encryption, optical data storage and quantum information sciences.

64 ntum objects, and is at the heart of quantum information sciences.

65 y new collaborations between biology and the information sciences.

66 ion not only from physics, but also from the information sciences.

67 s drawn from across the natural, social, and information sciences.

68 gration of social, natural, and geographical information sciences.

69 les present a versatile platform for quantum information science(1,2) and are candidates for sensing

70 m uniquely suited to applications in quantum information science(1-3), quantum simulation(4-6), ultra

71 quantum computation is a key goal in quantum information science(1-4).

72 xion searches(2) and superconducting quantum information science(3,4).

73 o the future, at the intersection of quantum information science and algorithms for correlated quantu

74 f quantum states enables advances in quantum information science and also contributes to the understa

75 ing the way for their application in quantum information science and energy conversion technologies.

76 tial applications, including many in quantum information science and engineering.

77 nt role in the future development of quantum information science and nano-photonics.

78 potential of solid-state qubits for quantum information science and nanoscale sensing.

79 igated for applications ranging from quantum information science and optoelectronics to high-resoluti

80 dual atoms and photons is central to quantum information science and precision measurement, and optic

81 systems is an outstanding problem in quantum information science and quantum communication.

82 ging quantum technologies, including quantum information science and quantum-assisted sensing.

83 There is a growing demand in quantum information science and sensing for electron spin purifi

84 ft altitudes using the Nanjing University of Information Science and Technology Earth System Model to

85 atomic systems is a central goal in quantum information science and technology.

86 ue to its application in quantum computation information science and technology.

87 to store and process information for quantum information science and technology.

88 bit registers is a key challenge for quantum information science and technology.

89 rties that has attracted interest in quantum-information sciences and as a design candidate for nanos

90 igence, cognitive science, computer science, information science, and social science.

91 bits have great potential for use in quantum information science applications because their structure

92 qubits are promising candidates for quantum information science applications because they can be rel

93 id organic inorganic perovskites for quantum information science applications has been recently propo

94 posals for low-power electronics and quantum information science applications.

95 platform for creating materials for quantum information science applications.

96 rays have great potential for use in quantum information science applications.

97 ion times to serve as spin qubits in quantum information science applications.

98 diamond nitrogen vacancy centers for quantum information science applications.

99 y (NV) centers and are promising for quantum information science applications.

100 er spin manipulation directed toward quantum information science applications.

101 for telecommunication, sensing, and quantum information science applications.

102 multi qubit/qudit ESP protocols for quantum information science applications.

103 ) make them promising candidates for quantum information science applications.

104 on a chip for a variety of photonic quantum information science applications.

105 nd operation at room temperature for quantum information sciences applications.

106 pervasive problem in biological, social and information sciences as correlation-based networks conta

107 able a wide range of applications in quantum information science, as has been demonstrated for solid-

108 evices, single-molecule magnets, and quantum information science at large.

109 Quantum information science attempts to exploit capabilities fro

110 a promising route to applications in quantum information science because they can be initialized into

111 ld great promise for applications in quantum information science because they can be prepared in well

112 ion strategy advances molecule-based quantum information science by providing a robust route toward s

113 Computer and information science can assist environmental biotechnolo

114 terials have attracted attention for quantum information science due to their ability to host single-

115 Advances in information science expanded NP-related databases, enabl

116 correlations-play a crucial role in quantum information science (for example, in demonstrations of q

117 ults constitute an important step in quantum information science, for example, toward the realization

118 Over the past several decades, quantum information science has emerged to seek answers to the q

119 The rise of quantum information science has spurred chemists to prepare new

120 Quantum information science has the potential to revolutionize m

121 ntum systems is an important tool in quantum information science; however, the large number of unknow

122 defects for critical applications in quantum information science, imaging, and sensing.

123 The results have applications in quantum information science, including for controlled interactio

124 ed to study a variety of problems in quantum information science, including performing more effective

125 ecules for precision measurement and quantum information science, including the search for an electro

126 Quantum information science involves the storage, manipulation a

127 uirement for diverse applications in quantum information science is the capability to disseminate qua

128 An outstanding goal in quantum information science is the faithful mapping of quantum i

129 The key challenge in experimental quantum information science is to identify isolated quantum mech

130 tion is essential to many aspects of quantum information science, it is important to establish this p

131 All sources of medical informatics and information science literature, including MEDLINE, along

132 As society adopts advanced tools in quantum information science, metrology, and sensing, microchip O

133 uld lead to multiple applications in Quantum Information Science, opening new perspectives for the sc

134 lds of optics, such as quantum and classical information science or optical tweezers.

135 ng on our own field of GIScience (geographic information science), our goal is to use the geographic

136 To advance quantum information science, physical systems are sought that me

137 SEM) report, Advancing Chemistry and Quantum Information Science, points to fundamental research area

138 munication is an important branch of quantum information science, promising unconditional security to

139 -standing goal in quantum optics and quantum information science, promising wide impact applications,

140 Active cooling of qubits, applied to quantum information science, provides a means for qubit-state pr

141 egy for advancing the development of quantum information science (QIS) applications.

142 Advancements in the field of Quantum Information Science (QIS) are expected to produce ground

143 ial challenge for the development of quantum information science (QIS) currently being explored by ch

144 systems are emerging candidates for quantum information science (QIS) due to their unique quantum be

145 chemical qubits, the core units of a quantum information science (QIS) system.

146 s important components for molecular quantum information science (QIS), especially in the context of

147 itions, with direct implications for quantum information science (QIS).

148 potential utility in spintronics and quantum information science (QIS).

149 ritical requirement for their use in quantum information science (QIS).

150 molecules will find applications in quantum information science, quantum sensors, fundamental and ap

151 Developments in quantum information science rely critically on entanglement-a fu

152 tum computing is an emerging area within the information sciences revolving around the concept of qua

153 lids are actively being explored for quantum information science, sensing, and imaging.

154 the promise of quantum materials for quantum information science superimposed with the potential of n

155 ation of qubits, the base units of a quantum information science system, designed for a target applic

156 Neutron-based studies of quantum information science, the foundations of quantum mechanic

157 Motivated by quantum information science, there has been a leap in the formul

158 ranging from quantum field theory to quantum information science to condensed matter physics.

159 pplicational interests, ranging from quantum information science to dark matter detectors.

160 studies of quantum entanglement and quantum information science to imaging.

161 es, methodologies, and tools in computer and information science to solve biological problems.

162 Geographic information science was then used to create satellite im

163 In an effort to exploit chemistry for information science, we have constructed a system to sen

164 ent structure holds great promise in quantum information science where there is a strong demand for e

165 stry enables a bottom-up approach to quantum information science, where atoms can be deterministicall

166 rials with potential applications in quantum information science, where incoherent relaxation process

167 otonics has become a mature field of quantum information science, where integrated optical circuits o

168 The scalable application of quantum information science will stand on reproducible and contr

169 We integrate theories from information science with control network theory into a f

170 al networks is a fundamental task in quantum information science with wide impact in physics, chemist

171 lecules are a promising platform for quantum information science, with the potential to enable scalab

172 and entanglement are fundamental to quantum information science, yet extending these effects to high