ライフサイエンスコーパス: magnetic material

1 any single-molecule magnet or molecule-based magnetic material.

2 ferromagnets may seem to behave like any non-magnetic material.

3 s considered the next-generation quantum and magnetic material.

4 ed through magnetic exchange coupling with a magnetic material.

5 s well as three-dimensional visualization of magnetic material.

6 hm of MTQC to determine the topology of each magnetic material.

7 pen-source code for diagnosing topologies of magnetic materials.

8 een developed by combining ferroelectric and magnetic materials.

9 ey to this new generation of multifunctional magnetic materials.

10 thereby improving our understanding of real magnetic materials.

11 such as water ice, spin ice, and frustrated magnetic materials.

12 associated with external magnetic fields or magnetic materials.

13 the directed synthesis of semiconducting and magnetic materials.

14 organizing nanowires from semiconducting and magnetic materials.

15 transition metal--containing electronic and magnetic materials.

16 delines for improving these high-performance magnetic materials.

17 ich will open new avenues in the field of 2D magnetic materials.

18 dict properties of such two-dimensional (2D) magnetic materials.

19 ology platform to advance the search for new magnetic materials.

20 re predominantly considered zero-dimensional magnetic materials.

21 ound in naturally occurring biomolecules and magnetic materials.

22 rgent field of two-dimensional van der Waals magnetic materials.

23 etry breaking magnetic order parameter of 2D magnetic materials.

24 copic scale in numerous application-relevant magnetic materials.

25 se for proton-based magneto-ionic control of magnetic materials.

26 ble spin structures that naturally emerge in magnetic materials.

27 hicles for the scalable synthesis of complex magnetic materials.

28 s will be important for ultrafast probing of magnetic materials.

29 esses, including the shaping/cutting of soft magnetic materials.

30 including the nature of the ground state in magnetic materials.

31 nveil the crucial roles of chiral phonons in magnetic materials.

32 tions as refractory coatings, catalysts, and magnetic materials.

33 have richer spin Hall properties than do non-magnetic materials.

34 but also in other settings such as laser and magnetic materials.

35 arning models to accelerate the discovery of magnetic materials.

36 tive and memory effects for a broad class of magnetic materials.

37 f new nd-4f single-molecule magnets and bulk magnetic materials.

38 iscover emergent topological solitons in non-magnetic materials.

39 ng interatomic potential for multi-component magnetic materials.

40 resents a step toward functional topological magnetic materials.

41 but also be of interest for realizing new 2D magnetic materials.

42 he design of high-performance molecule-based magnetic materials.

43 radicals is important for the development of magnetic materials.

44 ns, in particular as spin probes and organic magnetic materials.

45 structures, and introducing magnetism in non-magnetic materials.

46 er the system parameters than is possible in magnetic materials.

47 etization state of conducting and insulating magnetic materials.

48 ials, including polymers, semiconductors and magnetic materials.

49 near magnetostructural phase transitions in magnetic materials.

50 g and selective physical vapor deposition of magnetic materials.

51 ake it imperative to explore rare earth free magnetic materials.

52 otential as novel, rare-earth free permanent magnetic materials.

53 etism allowed light to be used as a probe of magnetic materials.

54 ipulation of the magnetization in engineered magnetic materials.

55 is responsible for a variety of phenomena in magnetic materials.

56 a feasible new route in realizing functional magnetic materials.

57 atures and also a basis for novel functional magnetic materials.

58 scopic length scale has long been pursued in magnetic materials(1-5).

59 yer exchange interactions in two-dimensional magnetic materials(15-18), we demonstrate a coexisting f

60 agnetic materials while tin entered into non-magnetic materials; (2) The tin-enriched non-magnetic ma

61 Moire engineering(1-3) of van der Waals magnetic materials(4-9) can yield new magnetic ground st

62 se results mark a crucial step in making vdW magnetic materials a viable choice for the development o

63 is using mixed-valence iron hydroxide as the magnetic material, a deep eutectic solvent as the coporo

64 rostructures formed by stacking together two magnetic materials, a ferromagnetic topological insulato

65 ted a high-throughput search for topological magnetic materials across 522 new, experimentally report

66 Magnetic materials, after achieving broad distribution f

67 In magnetic materials, an anomalous Nernst effect (ANE) is

68 These devices are now smaller, with less magnetic material and improved electromagnetic interfere

69 ich is a record for a rare earth- or Pt-free magnetic material and retain values as high as 17.1 MGOe

70 coercivity are key properties of functional magnetic materials and are generally associated with rar

71 stals composed of metals, semiconductors, or magnetic materials and capped with various MCC ligands c

72 w opportunities in drug delivery, as well as magnetic materials and devices.

73 , making them ideal building blocks in novel magnetic materials and devices.

74 This is essential for the design of new bulk magnetic materials and for diminishing processes such as

75 While SHE typically occurs in non-magnetic materials and is time-reversal even, exploring

76 This approach overcomes the limitations of magnetic materials and it does not require an external m

77 -reversal symmetry, typically achieved using magnetic materials and more recently using the quantum H

78 as originally studied as Barkhausen noise in magnetic materials and now is used in diverse fields fro

79 ailoring molecular spinterface between novel magnetic materials and organic semiconductors offers pro

80 perconducting architectures because they use magnetic materials and strong magnetic fields.

81 magnetic inverse SHE) that are absent in non-magnetic materials and that can be dominant in some magn

82 alities from thin layers of magnetic and non-magnetic materials and the interfaces between them.

83 ans of modulating the magnetic hystereses of magnetic materials and their heterostructures.

84 ce planarity but also the homogeneity of the magnetic materials, and our method is likely to find imm

85 nt magnetocaloric effects in a wide range of magnetic materials, and the parallel development of nano

86 Ferroelectric and magnetic materials are a time-honoured subject of study

87 Magnetic materials are composed of the simple building b

88 Novel nanostructured Zr2 Co11 -based magnetic materials are fabricated in a single step proce

89 The screening and discovery of magnetic materials are hindered by the computational cos

90 Nanostructured magnetic materials are important for many advanced appli

91 Zero- and one-dimensional magnetic materials are intriguing alternatives due to th

92 Frustrated magnetic materials are promising candidates for new stat

93 ciated with the elementary quasiparticles in magnetic materials are still underexplored.

94 Magnetic materials are usually divided into two classes:

95 Magnetic materials are widely used for many technologies

96 Magnons, the quanta of spin waves in magnetic materials, are promising for hybrid quantum sys

97 terministic magnetization switching in a vdW magnetic material at room temperature.

98 oxide, to prepare designed test platforms of magnetic materials at nanometer length scales.

99 alization of topological semimetal states in magnetic materials at room temperature, but also suggest

100 le very efficient electrical manipulation of magnetic materials at room temperature, for memory and l

101 hts into the design and synthesis of organic magnetic materials based on host-guest complexes.

102 to cobalt introduces potential new routes to magnetic materials based on strongly coupled, triangular

103 gation of disordered or distorted as well as magnetic materials, because it is not based on symmetry

104 to create an effective magnetic field in the magnetic material being probed, which makes it possible

105 They capture the properties of many magnetic materials, but also extend to other systems, su

106 etic anisotropy has been explored in various magnetic materials, but the efficient electric-field con

107 lver chalcogenides, Ag2Se and Ag2Te, are non-magnetic materials, but their electrical resistance can

108 s been the method of choice to magnetize non-magnetic materials, but they are difficult to focus.

109 g-standing goal to create magnetism in a non-magnetic material by manipulating its structure at the n

110 ddition improves the performance of the hard-magnetic material by mitigating Brown's paradox in magne

111 iated tissue preparation, cells that contain magnetic material by their rotational behavior.

112 elated to the recently proposed new class of magnetic materials called altermagnets(6-9).

113 ular, geometrical frustration among spins in magnetic materials can lead to exotic low-temperature st

114 Single layer magnetic materials can provide a pathway for vdW heteros

115 ructures that combine natural and artificial magnetic materials, can play a key role in terahertz dev

116 torage and separation, optical, electric and magnetic materials, chemical sensing, catalysis, and bio

117 An eco-friendly biomass waste-derived magnetic material coated with a dual-dummy-template mole

118 Altermagnets, an emerging class of magnetic materials, combine zero net magnetization with

119 Properties of many magnetic materials consisting of dipoles depend cruciall

120 plied this methodology to more than 4835 non-magnetic materials consisting of heavy atoms and low ban

121 the physical and magnetic properties of the magnetic material constituents and fabrication processes

122 to create a comprehensive, experiment-based, magnetic materials database named the Northeast Material

123 We use as our starting point the Magnetic Materials Database on the Bilbao Crystallograph

124 er of available materials on the Topological Magnetic Materials database.

125 nets (SMMs), which are an important class of magnetic materials due to their nanometre size, remain u

126 However, many commonly used magnetic materials (e.g., Ni and Co) are not biocompatib

127 s Database (NEMAD), which consists of 67,573 magnetic materials entries ( ).

128 Certain magnetic materials exhibit exotic hidden-order phases, i

129 agnetism can remove this obstacle, as chiral magnetic materials exhibit magneto-chiral dichroism, a d

130 TlReO(4) is a rare example of a non-magnetic material exhibiting a re-entrant phase transiti

131 e as building blocks for obtaining molecular magnetic materials exhibiting an additional and useful p

132 interest in the discovery and design of new magnetic materials exhibiting magnetoresistance.

133 esis of colloidal nanostructures combining a magnetic material (FePt) with a narrow-gap semiconductor

134 prepared in the L1(0) phase, as a promising magnetic material for biomedical applications with super

135 which in turn expands the base of available magnetic materials for devices with properties that cann

136 ticles (including metals, semiconductors and magnetic materials) form stable colloids in various molt

137 Magnetite, a naturally occurring magnetic material found in brain tissue, has been the su

138 The intended use of a magnetic material, from information storage to power con

139 cond-order magnetic phase transition in soft magnetic material, gadolinium, was employed to obtain me

140 ects of magnetic disorder and frustration in magnetic materials generally, but also highlight as desi

141 current technology, a search for a low-cost magnetic material has been more important than ever.

142 gh unconventional methods without the use of magnetic material has recently become a subject of great

143 The use of magnetic materials has been an effective approach for re

144 er, the limited availability of intrinsic 2D magnetic materials has driven efforts to induce and mani

145 The discovery of two-dimensional magnetic materials has provided an ideal platform for ex

146 nderstood as voltage-driven ion transport in magnetic materials, has largely relied on controlled mig

147 Molecule-based magnetic materials have been identified as promising can

148 Low-damping magnetic materials have been widely used in microwave an

149 Molecule-based magnetic materials have diverse magnetic functionalities

150 Magnetic materials having competing, i.e., frustrated, i

151 Two-dimensional van der Waals (vdW) magnetic materials hold promise for the development of h

152 agnetic insulators are a ubiquitous class of magnetic materials, holding the promise of low-dissipati

153 Complex magnetic materials hosting topologically non-trivial par

154 ow that by embedding nanoparticles of a soft magnetic material in a thermoelectric matrix we achieve

155 ice is mimicked by Dy2Ti2O7, a site-ordered magnetic material in which the spins reside on a lattice

156 coupling self-assembly to the generation of magnetic materials in a simple, straight-forward manner

157 Nonreciprocal optical elements often require magnetic materials in order to break time-reversal symme

158 pproach to carry out an efficient search for magnetic materials in the Bilbao Crystallographic Server

159 Simulating magnetic materials in the vicinity of a quantum phase tr

160 The only molecular-based magnetic materials in which this phenomenon has been obs

161 c materials and that can be dominant in some magnetic materials, including antiferromagnets.

162 transition materials, photomagnets, solvato-magnetic materials, including molecular magnetic sponges

163 ration and is readily implementable to other magnetic materials independent of their size and shape a

164 nical exchange coupling between Fe and Ni in magnetic materials influences magnetic switching dynamic

165 One currently active area of research in magnetic materials involves compounds in which long-rang

166 Our finding shows that optical control of magnetic materials is a much more general phenomenon tha

167 or spin-electric coupling) in molecule-based magnetic materials is a relatively nascent but promising

168 ization of two members of a family of porous magnetic materials is described.

169 bility to rapidly manipulate domain walls in magnetic materials is key to developing novel high-speed

170 The existence of NRM in homogenous magnetic materials is still in debate, mainly due to the

171 A key parameter in magnetic materials is the magnetic exchange coupling (ME

172 conversion of charge-to-spin currents in non-magnetic materials, is of considerable debate.

173 fect, extraordinarily strong among other non-magnetic materials, is traced back to the specific Dirac

174 The magnetic material KCuF3 realizes an array of weakly coup

175 ontaneously broken time-reversal symmetry in magnetic materials leads to a Hall response, with a nonz

176 ors typically associated with noncompensated magnetic materials like ferromagnets.

177 metal-to-insulator resistive switching in a magnetic material, local on/off control of ferromagnetis

178 As the oldest known magnetic material, magnetite (Fe3O4) has fascinated mank

179 e interplay between symmetry and topology in magnetic materials makes it possible to engineer exotic

180 Among potential multifunctional magnetic materials, metal-organic frameworks, in particu

181 spin-dependent thermoelectric properties of magnetic materials, novel means of generating spin curre

182 Palladium doped iron rhodium is a magnetic material of significant interest for it's close

183 temperature for any metal boride and for any magnetic material of the vast 122 family of layered stru

184 Here, we show that a new magnetic material offers novel possibilities for guiding

185 angement of spins at interfaces in a layered magnetic material often has an important effect on the p

186 However, correlated magnetic materials often do not support large SHEs.

187 dictive simulations of the dynamics of Ising magnetic materials on quantum simulators.

188 superconductors with strongly spin-polarized magnetic materials opens the possibility to discover new

189 In quantum magnetic materials, ordered phases induced by an applied

190 t permits high yield and rapid patterning of magnetic material over large areas.

191 esigning new rare-earth-free (REF) permanent magnetic materials (PMM) to replace the high performing

192 Nanostructured magnetic materials provide an efficient tool for light m

193 Similarly, the interaction of X-rays with magnetic materials provides unique element-specific cont

194 chiral magnets and photomagnets, SHG-active magnetic materials, pyro- and ferroelectrics, ionic cond

195 lizable optical readout method for molecular magnetic materials, reinforcing its potential for future

196 to targeted stimuli, they displace attached magnetic material relative to the phone's magnetometer.

197 These results suggest that a magnetic material's microstructure can be engineered to

198 In ordinary magnetic materials, single spin-flips give rise to colle

199 previous research has focused mainly on non-magnetic materials, so the magnetic contribution to the

200 Among the frustrated magnetic materials, spin-ice stands out as a particularl

201 it is possible to prepare molecule-based 2D magnetic materials stable at ambient conditions.

202 roperties in a broad range of high-frequency magnetic materials such as two-dimensional magnets, spin

203 constructs obtained by reconfiguring liquid magnetic materials, such as ferrofluid.

204 hniques to characterize other nanostructured magnetic materials, such as nanoparticles, is also revis

205 quest for a novel low-dimensional metal-free magnetic material that would exhibit magnetism at a high

206 re familiar realm of polymers, colloids, and magnetic materials that all exhibit thermal fluctuations

207 single-molecule magnets (SMMs), a family of magnetic materials that can retain magnetization in the

208 Altermagnets (AMs) are a new class of magnetic materials that combine the beneficial spintroni

209 Altermagnets, a unique class of magnetic materials that combines features of both ferrom

210 have revealed extraordinary spin dynamics in magnetic materials that equilibrium descriptions of magn

211 lassification of collinear, spin compensated magnetic materials that host net-zero magnetization yet

212 niobium magnet and, after discarding the non-magnetic material, the copper(II) ions were eluted with

213 In insulating quantum magnetic materials, the effects of disorder are less und

214 In certain magnetic materials, the maximum magnon group velocity se

215 In magnetic materials, the Pauli exclusion principle typica

216 In topological magnetic materials, the topology of the electronic wave

217 When interacting with magnetic materials, the wavefunctions of such electrons

218 nual disassembly allows in principle for all magnetic material to be recovered, shredding leads to ve

219 rporating newly discovered ferroelectric and magnetic materials to engineer symmetries and add a new

220 This approach is now being extended to magnetic materials to engineer their spin structures and

221 idase mimic for analyte detection), and as a magnetic material (to simplify the (bio)-sensing steps).

222 overy of emergent magnetism in van der Waals magnetic materials (vdWMM) has broadened the material sp

223 In the case of molecular magnetic materials, vibronic, or spin-phonon, coupling l

224 ef that grain boundaries are "weak links" in magnetic materials, we demonstrate grain boundaries unde

225 magnetic materials; (2) The tin-enriched non-magnetic materials were briquetted with CaCl(2) and anth

226 ve devices requires high-quality low-damping magnetic materials where magnon spin currents can effici

227 Metal-organic magnets (MOMs), modular magnetic materials where metal atoms are connected by or

228 nsition metal centers are a diverse class of magnetic materials where the spin density and ordering b

229 ens a new realm of possibility for molecular magnetic materials, where their unprecedented localized

230 ver, most soft machines are limited to solid magnetic materials, whereas further progress also relies

231 fficient spin detection without the need for magnetic materials, which could lead to useful spintroni

232 n process, and 90.8 wt% iron was enriched in magnetic materials while tin entered into non-magnetic m

233 nt with arbitrary polarization using typical magnetic materials will benefit the development of magne

234 nding and control of the dynamic response of magnetic materials with a three-dimensional magnetizatio

235 ffect was considered excluded in compensated magnetic materials with collinear ordering, in the recen

236 other hand, disordered freezing of spins in magnetic materials with decreasing temperature, the so-c

237 Two-dimensional (2D) magnetic materials with exotic magnetic properties have

238 The FePt/ferritin assemblies are integrated magnetic materials with ferritin providing added magneti

239 study indicates ingredients for engineering magnetic materials with high angular sensitivity by latt

240 The discovery of magnetic materials with high operating temperature range

241 ent important case studies in the pursuit of magnetic materials with inherently larger magnetic momen

242 y accomplished through the use of inherently magnetic materials with large magnetic permeability, suc

243 Results indicate that inclusion of magnetic materials with low magnetocrystalline anisotrop

244 The integration of magnetic materials with semiconductors will lead to the

245 e rise to multipolar magnetic excitations in magnetic materials with spin S >= 1.

246 Hard magnetic materials with strong perpendicular anisotropy

247 ociation reported here of the assembled soft magnetic materials with tuneable sizes could be interest

248 by integrating monolithic ferroelectric and magnetic materials, with interfacial coupling between el

249 l Hall effect has rarely been studied in non-magnetic materials without external magnetic fields, owi