ライフサイエンスコーパス: physical phenomena

1 ly dispersed spatial data and simulations of physical phenomena.

2 maging, microscopy, and tests of fundamental physical phenomena.

3 lays a significant role in many chemical and physical phenomena.

4 lications for our understanding of important physical phenomena.

5 levant lengths to the nanoscale produces new physical phenomena.

6 mathematical models to obtain insights into physical phenomena.

7 aterial system promises the emergence of new physical phenomena.

8 but also interesting for driving other novel physical phenomena.

9 ng, is a model applicable to a wide range of physical phenomena.

10 ntum processors are beginning to uncover new physical phenomena.

11 material remains one of the most intriguing physical phenomena.

12 ecedented opportunities to create remarkable physical phenomena.

13 ground for exploring chirality-driven exotic physical phenomena.

14 connected with the undecidability of certain physical phenomena.

15 models that can be used to study unexplored physical phenomena.

16 issimilar layered materials and induce novel physical phenomena.

17 l for investigating ultrafast biological and physical phenomena.

18 er a rare platform for realizing many exotic physical phenomena.

19 bandgap can allow for the exploration of new physical phenomena.

20 stems, and their study has shed light on new physical phenomena.

21 dom provides a plethora of exotic phases and physical phenomena.

22 lead to the realization of several predicted physical phenomena.

23 g across a range of biological, chemical and physical phenomena.

24 cal and mechanical devices and display novel physical phenomena.

25 amatically when compared to macroscale fluid physical phenomena.

26 it a flexible platform for exploring exotic physical phenomena.

27 rovide a unique test bed for low-dimensional physical phenomena.

28 ems in confined geometries are host to novel physical phenomena.

29 om single ion channels, as well as for other physical phenomena.

30 ts in this system show a plethora of diverse physical phenomena.

31 ensuring the robustness of a wide variety of physical phenomena.

32 ox potential, chemical reactions and various physical phenomena.

33 x and involves a large number of species and physical phenomena, a comprehensive understanding of the

34 onal materials, which often exhibit striking physical phenomena absent in their bulk form.

35 Trapped bosons exhibit fundamental physical phenomena and are at the core of emerging quant

36 es at room temperature also exhibit emergent physical phenomena and are of great promise for optoelec

37 properties as well as the emergence of novel physical phenomena and device functionality.

38 iquids are an exciting playground for exotic physical phenomena and emergent many-body quantum states

39 est, motivated by the possibility to explore physical phenomena and engineering opportunities beyond

40 rostatic control of oxide interfaces enables physical phenomena and exotic functionalities beyond the

41 extensively studied as templates for unique physical phenomena and in the design of reconfigurable e

42 rconducting structures have revealed various physical phenomena and led to the development of a wide

43 ly available specimens mask many anticipated physical phenomena and limit device applications of TMDC

44 esent a new class of matter with both exotic physical phenomena and novel application potentials.

45 olarization textures that demonstrate exotic physical phenomena and novel memory applications.

46 terest due to their richness in chemical and physical phenomena and potential for technological appli

47 -strong, coupling regimes can exhibit exotic physical phenomena and promise new applications in quant

48 is given with an emphasis on the fundamental physical phenomena and quantized electronic transitions

49 Here, the physical phenomena and sensing principles of plasmonic a

50 -Hermitian physics, giving rise to plenty of physical phenomena and strategies to develop advanced de

51 of further exploration of these interesting physical phenomena and their potential applications in n

52 d as being a unique platform to discover new physical phenomena and to design novel functionalities i

53 f freedom, making it possible to explore new physical phenomena and to foresee novel applications in

54 stems play an important role in studying new physical phenomena and unconventional thermodynamics.

55 tor has the potential to give rise to exotic physical phenomena and useful device applications.

56 to leverage spatial principles in simulating physical phenomena and, by extension, advance the physic

57 already demonstrated a range of fascinating physical phenomena, and have also been used in demonstra

58 Special relativity asserts that physical phenomena appear the same to all unaccelerated

59 The physical phenomena are complex and nonintuitive, and so

60 is also the primary lens through which many physical phenomena are defined and interpreted.

61 d at the quantum level, the presumption that physical phenomena are fundamentally determinate seems t

62 ffers the potential for the discovery of new physical phenomena, as well as a better understanding of

63 performance, but also prevents the study of physical phenomena associated with an extended pi-electr

64 A variety of physical phenomena associated with nanoscale electron tr

65 The primary physical phenomena associated with ultrasound that are r

66 Understanding the emergent physical phenomena at surfaces requires the capability t

67 damentals of ECR, including the chemical and physical phenomena at the electrodes as well as the elec

68 technological potential, along with the rich physical phenomena at the interface, has sparked intensi

69 abling the study of biological, material and physical phenomena at the nanometre scale.

70 ficant change in the relative proportions of physical phenomena attributed to genetic causes, but the

71 ta, indicating that the functional can cover physical phenomena behind adsorption of organic molecule

72 n solids enables the discovery of correlated physical phenomena, but applying it for the development

73 eting has been elaborated in studying purely physical phenomena, but there can be found therein many

74 le dimensions of these devices introduce new physical phenomena by confining the biomolecules in at l

75 heat currents, electric currents, and other physical phenomena by coordinate transformation methods

76 Many physical phenomena can be understood by single-particle

77 Many physical phenomena create colour: spectrally selective l

78 Many physical phenomena deviate from their established framew

79 hematical models to account for two proposed physical phenomena driving periphery sequestration: biof

80 The physical phenomena driving this periphery sequestration

81 The understanding of the physical phenomena during the interaction of a laser bea

82 lectron-phonon coupling is important in many physical phenomena, e.g. photosynthesis, catalysis and q

83 ystems that can benefit from the rich set of physical phenomena enabled by their non-Hermitian descri

84 rich material base for exploring many exotic physical phenomena (for example, chiral magnetic effects

85 s to experimental data on a diverse range of physical phenomena, from conductance in granular metals

86 For the first time, novel physical phenomena have been observed at these dramatica

87 It hybrids multiple physical phenomena i.e. magnetic flux leakage, induced e

88 Two physical phenomena-(i) spontaneous and rapid self-dewett

89 This work provides new insights into the physical phenomena in BPMs and helps identify optimal op

90 tum spin correlations underlies a variety of physical phenomena in condensed-matter systems, potentia

91 rical breakdown is one of the most important physical phenomena in electrical and electronic engineer

92 mensions have been proposed for the study of physical phenomena in high dimensions and interacting ph

93 y and document analytical laws that underlie physical phenomena in nature.

94 junctions as molecular switches, and general physical phenomena in single-molecule electronic devices

95 mental for understanding a vast diversity of physical phenomena in solid-state systems, including top

96 es highlighting its relevance to fundamental physical phenomena in solids, measuring the complete qua

97 atic liquid crystals model a wide variety of physical phenomena in systems that rapidly switch betwee

98 materials, as well as the potential for rich physical phenomena in the Ln(3)MPn(5) family.

99 Many physical phenomena in the ocean involve interactions bet

100 ies using the combination of three different physical phenomena in the same channel of the SPR analyz

101 has provided an ideal platform for exploring physical phenomena in the two-dimensional limit.

102 it coupling are known to give rise to exotic physical phenomena in transition metal oxides.

103 and heterostructures opens vistas into novel physical phenomena including magnetoelectric coupling an

104 termines the characteristics of a variety of physical phenomena, including catalysis, electrochemistr

105 y of oxide surfaces affects a broad range of physical phenomena, including mineral dissolution and so

106 ize area have been extensively used to model physical phenomena, including soap films, black holes, c

107 They also exhibit a variety of new physical phenomena, including suppression or enhancement

108 ferromagnetic metals and discoveries of new physical phenomena involving electron spin.

109 expanding interest in ultrafast chemical and physical phenomena, it has become important to develop t

110 Remarkably little is known about the physical phenomena leading to nucleation of new perfect

111 biological processes such as endocytosis and physical phenomena like phase separation in lipid bilaye

112 nsional materials realise novel and enhanced physical phenomena, making them attractive research targ

113 ibited by cell membranes enables a wealth of physical phenomena, many of which also have biological f

114 of two-dimensional materials have shown new physical phenomena, novel electronic and optical propert

115 nditions during seismic slip, many competing physical phenomena occur (like mineral decomposition, na

116 hat such a model is inadequate and that many physical phenomena occur during grain boundary migration

117 Critically, the physical phenomena occurring form the basis of the model

118 ics was developed considering alterations of physical phenomena occurring in microgravity, such as bu

119 a simplified model for numerous fascinating physical phenomena occurring on size scales from the cel

120 include measurement error in addition to the physical phenomena of interest.

121 's magnetic field, one of the most enigmatic physical phenomena of the planet, is constantly changing

122 interesting, because they often involve new physical phenomena or new compositions that defy expecta

123 ivity and circular dichroism are fascinating physical phenomena originating from the interaction of l

124 sitions for switching and control over other physical phenomena, particularly those relying on struct

125 Understanding physical phenomena peculiar to nanoconfined water paves

126 quid electrolyte is governed by two distinct physical phenomena: quantum and chemical.

127 Knots and knotted fields enrich physical phenomena ranging from DNA and molecular chemis

128 d graphene-boron nitride layers, interesting physical phenomena ranging from Fermi velocity renormali

129 by presenting the theoretical principles of physical phenomena represented by mathematical descripti

130 dels can systematically evaluate how various physical phenomena such as diffusion, swelling, dilution

131 ives rise to very interesting spin-dependent physical phenomena such as the Edelstein and inverse Ede

132 ces could also give rise to many fascinating physical phenomena, such as chiral magnon and skyrmion g

133 offers a convenient toolbox to identify new physical phenomena, such as chiral phonons and their pro

134 Our findings suggest that ubiquitous physical phenomena, such as nucleation, may hold powerfu

135 s have already led to the observation of new physical phenomena, such as the metal-insulator transiti

136 ids plays an essential role in modeling many physical phenomena, such as weather, climate, aerodynami

137 viour of phase is crucial for many important physical phenomena, such as, for example, the Aharonov-B

138 This review highlights the unique physical phenomena surrounding this class of polycyclic

139 de heterostructures exhibit a range of novel physical phenomena that are absent in the parent compoun

140 Among all the physical phenomena that are enabled by Weyl semimetals,

141 dimensions to demonstrate lattice models and physical phenomena that are not accessible to experiment

142 erimental studies to portray the fundamental physical phenomena that can explain the alteration of th

143 ure X-ray structure provide insight into the physical phenomena that control the electronic modulatio

144 and metallic Fe(3)GeTe(2)-and illustrate the physical phenomena that have been observed.

145 that quantum simulators can be used to study physical phenomena that have not yet been observed in an

146 ary researchers strive to understand complex physical phenomena that involve many constituents, may b

147 quiescent plasma-one of the most fundamental physical phenomena that makes plasma different from a co

148 ew, we explore the multiscale biological and physical phenomena that underlie the simultaneous fulfil

149 which are also predicted to give rise to new physical phenomena that would be absent in a planar two-

150 ases have far-reaching impacts both from the physical phenomena they reveal and the technologies they

151 By invoking a more complete set of physical phenomena, this new model will enable represent

152 and control of their structures and emergent physical phenomena through epitaxial strain, layer thick

153 pens the door to discover new mechanisms and physical phenomena through integration of quantum materi

154 e but also open a route for exploring exotic physical phenomena through phonon properties in Weyl sem

155 f spectral information arising from distinct physical phenomena to assess which was most important fo

156 of two-dimensional crystals, they allow rich physical phenomena to be probed at the quantum level.

157 short timescale by actively exploiting local physical phenomena to develop communities and efficientl

158 n avenue to uncover technologically relevant physical phenomena unattainable in bulk materials.

159 A bottom-up approach to understand the physical phenomena underlying challenges in separations

160 The main physical phenomena were water loss during grilling, and

161 that the correlation may be caused by other physical phenomena with decadal periods or by a response

162 Using CUP, we visualize four fundamental physical phenomena with single laser shots only: laser p