ライフサイエンスコーパス: electromagnetic field

1 nto states that are hybridized to the vacuum electromagnetic field.

2 programmable frequency and force level in an electromagnetic field.

3 tral response and the significantly enhanced electromagnetic field.

4 um mechanics and the gauge invariance of the electromagnetic field.

5 y of Raman labels to experience strong local electromagnetic field.

6 model of communication with a fully quantum electromagnetic field.

7 gains can be made by manipulating the local electromagnetic field.

8 on the nanometre scale, producing an intense electromagnetic field.

9 orders of magnitude larger than the incident electromagnetic field.

10 ed by application of an external alternating electromagnetic field.

11 uantum mechanical vacuum fluctuations of the electromagnetic field.

12 es the response of the system to an external electromagnetic field.

13 nergy transfer between the electrons and the electromagnetic field.

14 d governs the OAM generation in the outgoing electromagnetic field.

15 tions inside the system are distorted by the electromagnetic field.

16 tion is generated as a complex-valued output electromagnetic field.

17 tightly-confined and exponentially-decaying electromagnetic field.

18 dielectric environment for manipulating the electromagnetic field.

19 signal due to the effective coupling of the electromagnetic field.

20 nted level of confinement and enhancement of electromagnetic field.

21 coupling between the magnetic dipole and the electromagnetic field.

22 excitations of free charges (plasmons) with electromagnetic fields.

23 ting the phase, amplitude or polarization of electromagnetic fields.

24 s, can be sensitively controlled by external electromagnetic fields.

25 ared, the atrial lead is more susceptible to electromagnetic fields.

26 mood using a previously unexplored range of electromagnetic fields.

27 perature, pressure, surface realignment, nor electromagnetic fields.

28 biperylene derivative by precisely sculpted electromagnetic fields.

29 structures that couple strongly to external electromagnetic fields.

30 ice performs a coordinate transformation for electromagnetic fields.

31 s design and to the cloaking of objects from electromagnetic fields.

32 ed volume of space to exclude completely all electromagnetic fields.

33 sures to residential extremely low frequency electromagnetic fields.

34 o degrees of freedom are used to predict the electromagnetic fields.

35 detect and control material properties with electromagnetic fields.

36 Bose-Einstein condensates (BECs) coupled to electromagnetic fields.

37 th nanometer precision to regions of intense electromagnetic fields.

38 coherently manipulated by means of external electromagnetic fields.

39 lving integral equations using monochromatic electromagnetic fields.

40 is correlated with this rapid heating under electromagnetic fields.

41 oupled by interactions mediated by scattered electromagnetic fields.

42 ly inaccessible due to the large TMS-induced electromagnetic fields.

43 al mechanism through real-time processing of electromagnetic fields.

44 uantum particles(1-11) and their coupling to electromagnetic fields(12-18).

45 -12) and well known for their sensitivity to electromagnetic fields,(13-20) whether this ability is u

46 advantage is its supposed immunity to strong electromagnetic fields, a crucial feature in many enviro

47 ombination with a low frequency (150 kHz) AC electromagnetic field (AC EMF) to effectively remove tri

48 an ideal platform to investigate how vacuum electromagnetic fields affect strongly correlated electr

49 ires and at surface defects where heightened electromagnetic fields affect the fluorescence.

50 ation of the strong local enhancement of the electromagnetic field allows enhancing the optical emiss

51 significantly correlated with the estimated electromagnetic field amplitudes both for absolute metab

52 the transfer of energy between the turbulent electromagnetic field and electrons in the Earth's magne

53 monic nanostructures to confine the incident electromagnetic field and increase it by many orders of

54 of coherent quantum interactions between the electromagnetic field and matter inside a resonator, has

55 iving a topological magnon insulator with an electromagnetic field and show that this causes edge mod

56 nd circadian disruption was evaluated in the Electromagnetic Fields and Breast Cancer on Long Island

57 The ideal study of occupational exposure to electromagnetic fields and cancer risk would have a clea

58 mechanism for the transfer of energy between electromagnetic fields and charged particles.

59 l systems, reducing nanotoxicity, modulating electromagnetic fields and contacting nanostructures.

60 esearchers to modify the interaction between electromagnetic fields and dielectric media from radio t

61 tic interferences between various sources of electromagnetic fields and ICDs in daily life and occupa

62 In this work, spacecraft measurements of the electromagnetic fields and ion velocity distributions by

63 d efficient platforms for dynamic control of electromagnetic fields and optical responses.

64 tential approach for energy exchange between electromagnetic fields and plasma particles, neither the

65 This permits the visualization of the electromagnetic fields and polarization surface charge d

66 due to their ability to confine and enhance electromagnetic fields and strong, inherent nonlinearity

67 nding the fundamental properties of confined electromagnetic fields and the development of advanced p

68 ctrons at low [Formula: see text] Spectra of electromagnetic fields and the ion distribution function

69 s, including concerns related to nonionizing electromagnetic fields and wireless mobile telephones.

70 n effective decoupling of the qubit from the electromagnetic field, and that this effect is observabl

71 reasons: high temperature, high surrounding electromagnetic field, and the highly corrosive molten s

72 regulated by using external fields, such as electromagnetic fields, and a theoretical approach has b

73 c devices at extreme temperatures, intensive electromagnetic fields, and radiation found in space exp

74 ed functional imaging; detection of neuronal electromagnetic fields; and molecular imaging of neural

75 s for the case of an infinite cylinder in an electromagnetic field are well known, and have been used

76 the amplitude, phase and polarization of the electromagnetic fields are accrued gradually along an op

77 The risks of extremely-low frequency (ELF) electromagnetic fields are particularly poorly understoo

78 Biological electromagnetic fields arise throughout all tissue depth

79 , the Raman signal is amplified by localized electromagnetic fields around the nanopores and carefull

80 study explored parental exposure to heat and electromagnetic fields as potential risk factors.

81 For strong electromagnetic fields, as the supercurrents approach th

82 s in or on the body, which may be subject to electromagnetic fields associated with the MR system.

83 on in the metal nanoparticle oriented by the electromagnetic field at the laser focus.

84 Tailoring the electromagnetic field at the nanoscale has led to artifi

85 changes from 1 to 0, which leads to enhanced electromagnetic fields at material interfaces and a rect

86 We find strong focusing of the electromagnetic fields at the contact edges over the sam

87 Confinement of electromagnetic fields at the subwavelength scale via me

88 plasmon polariton), creating large localized electromagnetic fields at their interface, where 4-MBA m

89 Unlike for the electromagnetic field, Bohr's argument does not imply th

90 ible without the complications of driving an electromagnetic field but rather by using spin-polarized

91 ht, its electrons can absorb energy from the electromagnetic field by rapidly rearranging their posit

92 Some of these systems will be coupled to the electromagnetic field by the charge distributions they c

93 etween the magnetic dipole of a spin and the electromagnetic field can be enhanced up to the point at

94 ltimate limit of a single nanostructure, the electromagnetic field can be strongly concentrated in a

95 ns, (macro)molecules, hydrodynamic flows, or electromagnetic fields can be directly observed under th

96 sign that metamaterials provide, we show how electromagnetic fields can be redirected at will and pro

97 Dynamic control with pulsed electromagnetic fields can overcome energetic barriers,

98 estation of the fact that, even in a vacuum, electromagnetic fields cannot all vanish.

99 ldhood leukaemia and extremely low-frequency electromagnetic fields cannot be dismissed entirely.

100 However, the influence of electromagnetic fields, charge transfer, and molecular g

101 we demonstrate that the naturally occurring electromagnetic field chirality that arises in nanobeam

102 n improved capability to efficiently use the electromagnetic field compared to other structures.

103 first application, we investigated the bound electromagnetic field component of surface phonon polari

104 ct from weak thin-film interference, intense electromagnetic fields confined within the epsilon-near-

105 Here we demonstrate several schemes of electromagnetic field confinement aimed at facilitating

106 rdles in plasmonics is the trade-off between electromagnetic field confinement and the coupling effic

107 otonics mostly due to their intrinsic strong electromagnetic field confinement, ultraslow polariton g

108 Strong interactions, better electromagnetic field confinements, and less leakage int

109 , has predicted that quantum fluctuations of electromagnetic fields could induce phonon coupling acro

110 bling tailoring of the damping processes and electromagnetic field couplings of the Fano resonances,

111 Atoms interact with each other through the electromagnetic field, creating collective states that c

112 Electrical stimulation (pulsed electromagnetic fields, direct current, and capacitive c

113 Highly localized electromagnetic field distributions near the "shadow-sid

114 Extremely low-frequency daily-life electromagnetic fields do not disturb sensing capabiliti

115 exposure to extremely low-frequency (50 Hz) electromagnetic fields (ELF MFs) on a recognition memory

116 ed the mean level of extremely low-frequency electromagnetic fields (ELF-EMFs) to which populations a

117 of clinical and experimental data regarding electromagnetic field (EMF) bioeffects and their therape

118 er and the electro-sensitive Little skate to electromagnetic field (EMF) emissions of a subsea high v

119 While increasing frequency of electromagnetic field (EMF) exposure (up to <10 kHz) of

120 idely used metric for studies of residential electromagnetic field (EMF) exposure and health effects.

121 ferentiation, and therefore the potential of electromagnetic field (EMF) exposure to induce cancer.

122 d with the human btk gene to a 1-gauss 60-Hz electromagnetic field (EMF) has been reported to rapidly

123 Electromagnetic field (EMF) is a cost-effective, simple,

124 osure of DT40 lymphoma B cells to low energy electromagnetic field (EMF) results in a tyrosine kinase

125 Electromagnetic fields (EMF) are physical energy fields

126 Exposure to electromagnetic fields (EMF) has been associated with th

127 osure of DT40 lymphoma B-cells to low energy electromagnetic fields (EMF) results in activation of ph

128 the possible association between exposure to electromagnetic fields (EMFs) and breast cancer.

129 Electromagnetic fields (EMFs) are present throughout the

130 Exposure to electromagnetic fields (EMFs) from use of electric blank

131 and tissue cultures generated using induced electromagnetic fields (EMFs) in an air-core solenoid co

132 The reports dealing with the effects of electromagnetic fields (EMFs) on brain electrical activi

133 association between occupational exposure to electromagnetic fields (EMFs) or polychlorinated bipheny

134 Electric fields (E) and electromagnetic fields (EMFs) were calculated under idea

135 Drosophila melanogaster also respond to electromagnetic fields (EMFs), although the reported eff

136 f polarization in the biological activity of Electromagnetic Fields (EMFs)/Electromagnetic Radiation

137 lar (LV) endocardial mapping procedure using electromagnetic field energy for positioning of the cath

138 able to the decay length of the LSPR-induced electromagnetic field enhancement ( approximately 5-20 n

139 e-enhanced Raman scattering (SERS) relies on electromagnetic field enhancement at optical frequencies

140 concentrated within the 0-4 nm thick zone of electromagnetic field enhancement.

141 f the nanoparticles while also mapping local electromagnetic field enhancements and reactivity patter

142 ing resonant molecular excitation with large electromagnetic field enhancements experienced by a mole

143 ong interparticle interactions lead to large electromagnetic field enhancements that can be exploited

144 spots using single molecules to probe local electromagnetic field enhancements.

145 l intensity by 9 orders of magnitude through electromagnetic field enhancements.

146 microscopy (TIRM) an exponentially decaying electromagnetic field established on the surface of a gl

147 a number of previous studies of occupational electromagnetic field exposure and cancer, additional st

148 dd modest support for an association between electromagnetic field exposure and leukemia.

149 y low frequency and radiofrequency/microwave electromagnetic field exposure and no association betwee

150 tric blankets, one of the largest sources of electromagnetic field exposure in the home, is associate

151 Animal studies have shown that electromagnetic field exposure may interfere with the ac

152 investigate the relation between a range of electromagnetic field exposures and brain tumor risk in

153 the conservative energy exchange between the electromagnetic field fluctuations and the charged parti

154 om the polymer by external application of an electromagnetic field for 2h/day for a week.

155 esults indicate that extremely low frequency electromagnetic fields from commonly used household appl

156 real space to take the quantum nature of the electromagnetic field fully into account.

157 d dramatically increase the intensity of the electromagnetic field, functioning as high performance p

158 ay occur when the pacemaker is exposed to an electromagnetic field generated by the cellular telephon

159 The highly enhanced electromagnetic field generated by the plasmon coupling

160 Electromagnetic fields generated by neuronal activity in

161 itable tissues is essential for relating the electromagnetic fields generated by the tissue to the un

162 Here, we measure the amplification of an electromagnetic field, generated by a toroid LC-circuit,

163 Here, we show that superchiral electromagnetic fields, generated by the optical excitat

164 nsor coils were spatially tracked through an electromagnetic field generator.

165 e result of diffusion, orientation, or local electromagnetic field gradients but rather are the resul

166 Men who were exposed to nonionizing electromagnetic fields had a small excess risk for devel

167 iquitous dipole interaction with a classical electromagnetic field has to be modified in real space t

168 ive response of positive-energy electrons to electromagnetic fields has been explored through ionizat

169 m vacuum noise, which stems from fluctuating electromagnetic fields, has shown promise for high speed

170 limited coupling of these resonances to the electromagnetic field have not generally been considered

171 Most studies of current responses to electromagnetic fields have focused on optical intensity

172 perature environments and exhaust fumes, but electromagnetic fields have not been implicated.

173 The ability to control electromagnetic fields, heat currents, electric currents

174 e samples to an intense interaction with the electromagnetic fields highly concentrated around the se

175 the two platforms generates locally enhanced electromagnetic field 'hot spot', formed at the junction

176 tiple-branched petals with an enhanced local electromagnetic field, (ii) long narrow gaps between adj

177 by modifying the vacuum fluctuations of the electromagnetic field in a cavity.

178 By preparing a microwave-frequency electromagnetic field in a squeezed state and near-noise

179 caused by the interaction of matter and the electromagnetic field in subwavelength resonant structur

180 f the closely attached AuNPs, and the strong electromagnetic field in the cavity of the AuNP shell or

181 We proved the high confinement of the electromagnetic field in the holes both by theoretical m

182 ecade has seen subwavelength focusing of the electromagnetic field in the proximity of nanoplasmonic

183 eflection band due to evanescent coupling of electromagnetic field in the slab and the buffer layer.

184 The optical ruler is a complex electromagnetic field in which singularities serve as th

185 ic oscillators in the quantum regime include electromagnetic fields in a cavity and the mechanical mo

186 Plasmon-enhanced electromagnetic fields in an array of gold nanodots prov

187 Depending on the applied strength, electromagnetic fields in electronic materials can induc

188 is ultrafast charge transport and control by electromagnetic fields in semiconductors.

189 Surface plasmon polaritons can confine electromagnetic fields in subwavelength spaces and are o

190 These structures allow for concentration of electromagnetic fields in the desired locations between

191 esonance from metal nanoparticles to enhance electromagnetic fields in the region of analytes.

192 the calculation of physical quantities like electromagnetic fields in the relativistic regime.

193 Here, we realize a two-mode cat state of electromagnetic fields in two microwave cavities bridged

194 on path for applications where tailoring the electromagnetic field induced by Fano resonance can impr

195 neous yet powerful volumetric confinement of electromagnetic field inside an open-access nanotip.

196 he finite zero point energy of the quantized electromagnetic field inside an optical cavity.

197 t concerns water response to radio frequency electromagnetic fields inside biological matter or near

198 the limit set by quantum fluctuations of the electromagnetic field instead of thermal or technical no

199 eatly enhanced sensitivity (due to increased electromagnetic field intensities at the dielectric surf

200 Little is known about how electromagnetic fields interact with this layer, particu

201 ain no metallic iron, and research involving electromagnetic field interactions with regolith would b

202 gular grooves which effectively confines the electromagnetic field into a slow travelling wave.

203 as a resonator that accumulates an intensive electromagnetic field into a spiral capacitive gap (arou

204 s tiny antennae for efficiently focusing the electromagnetic field into nanoscale volumes.

205 d engineering by providing schemes to tailor electromagnetic fields into desired spatial patterns.

206 Strong resonant modulation of the incident electromagnetic field is achieved thanks to the exceptio

207 The electromagnetic field is assigned a self-consistent role

208 ature are separated by nanoscale gaps and an electromagnetic field is localized within the gaps.

209 ion (MSM), since the flux of an AC-generated electromagnetic field is used to induce physical movemen

210 etween striped charge fluctuations and local electromagnetic fields is especially important, as it af

211 The disruptive effect of radiofrequency electromagnetic fields is not confined to a narrow frequ

212 of a single spatial and temporal mode of the electromagnetic field, linear amplifiers can be classifi

213 Mechanisms by which weak electromagnetic fields may affect biological systems are

214 Electromagnetic fields may be chiral, too, with circular

215 ility that weak, low-frequency anthropogenic electromagnetic fields may have biological consequences.

216 Some investigators have posited that electromagnetic fields may influence cancer risk through

217 cylinder acts as an amplifier of a rotating electromagnetic field mode.

218 g electric currents are set up that generate electromagnetic field moments; these can lead to dramati

219 ementary quantum mechanics requires that the electromagnetic field must be quantized.

220 Nanoscale localization of electromagnetic fields near metallic nanostructures unde

221 With TIRM, an exponentially decaying electromagnetic field (near-field) established on the su

222 and poly(benzyl methacrylate) to the vacuum electromagnetic field of the cavity enhances the electri

223 only the rapidly oscillating (1 kHz, <1 V/m) electromagnetic field of the experimental procedure, cal

224 Probing the electromagnetic field of the hotspots would offer much i

225 interaction of the object with the fringing electromagnetic field of the QCM.

226 ytic reactions conditioned by enhanced local electromagnetic fields of localised plasmons.

227 ed from solution to occupy sites of enhanced electromagnetic field on the substrate by means of chemi

228 s that measure the amplitude and phase of an electromagnetic field on very large areas.

229 lly tune the interaction and localization of electromagnetic fields on semiconductor surfaces in a wa

230 is due to the increase in the confinement of electromagnetic fields on the location of the SLG that r

231 ions of electrons (plasmons), providing huge electromagnetic fields on the nanometer scale.

232 ing the electrical signal by radio frequency electromagnetic fields on the nanosecond time scale, lim

233 e spatial distribution of resonantly coupled electromagnetic fields on the photonic crystal surface a

234 positioned near regions of strongly enhanced electromagnetic fields on the surface of nano-featured p

235 chnique to produce and then image evanescent electromagnetic fields on the surfaces of nanostructures

236 owever, no significant effects of low-energy electromagnetic fields on tyrosine kinase activities or

237 ing is due to the qubit interacting with the electromagnetic field only through its toroidal moment,

238 serious damage to instruments due to strong electromagnetic fields or arcing.

239 terrestrial or cosmic ionising radiation, to electromagnetic fields, or to nuclear energy?

240 surface design parameters based on a desired electromagnetic field outcome.

241 Pulsed electromagnetic fields (PEMF) have been shown to be clin

242 Brief exposure to low mT-range pulsing electromagnetic fields (PEMFs) was previously shown to a

243 Detecting weak radio-frequency electromagnetic fields plays a crucial role in a wide ra

244 h 15 nm resolution as a function of time and electromagnetic field polarization for different plasmon

245 y low frequency and radiofrequency/microwave electromagnetic field potential exposures were estimated

246 However, strong 50-Hz electromagnetic fields, present in certain occupational

247 d by measuring the polarisation state of the electromagnetic fields produced by a microstrip waveguid

248 The forward and backward propagating electromagnetic fields produced by the waveguide, in a s

249 Electromagnetic fields produced by thermal fluctuation c

250 s, based both on the exact solutions for the electromagnetic field propagating in the helical plasmon

251 frames per second) video images and wideband electromagnetic field records of the attachment process

252 How living systems respond to weak electromagnetic fields represents one of the major unsol

253 led and perceived exposure to radiofrequency electromagnetic fields (RF-EMF) from mobile-phone base s

254 Radio-frequency electromagnetic fields (RF-EMFs) can be absorbed in all

255 ociation between exposure to radio-frequency electromagnetic fields (RF-EMFs) from broadcast transmit

256 Exposures to radiofrequency electromagnetic fields (RF-EMFs, 100 kHz to 6 GHz) have

257 ng qubits(5), high-resolution and high-speed electromagnetic-field sensing(8) and high-accuracy curre

258 -dimensional (3D) optical lens structure for electromagnetic field shaping based on spatial light tra

259 model consists of an accurate body model for electromagnetic field simulations, an atlas of periphera

260 ity and exposure to shift work, metal fumes, electromagnetic fields, solvents, lead, paint, pesticide

261 Meanwhile, electric and electromagnetic fields stay within the bounds allowed by

262 In the realm of very strong electromagnetic fields such as in the heaviest highly ch

263 imodal nature of the interaction between the electromagnetic fields, such as phase noises and spontan

264 of the local degree of chiral dissymmetry in electromagnetic fields suggested the existence of optica

265 d to vibrate with the flux of an external ac electromagnetic field, supplied by a wire coil solenoid

266 that are enhanced by the highly concentrated electromagnetic fields supported by the resonant whisper

267 order of molecules that can be controlled by electromagnetic fields, surface modifications and pressu

268 from the characteristic decay length of the electromagnetic fields surrounding Ag nanoparticles bein

269 We calculate the electromagnetic field tensor for general three dimension

270 We then compare the electromagnetic field tensors obtained by a direct boost

271 bstrates is attributed to the enhanced local electromagnetic field that originates from coupling betw

272 ydrogen-like bismuth (209)Bi(82+) experience electromagnetic fields that are a million times stronger

273 ions, known as plasmons, can have evanescent electromagnetic fields that are orders of magnitude larg

274 s are scattered and accelerated by turbulent electromagnetic fields that isotropize the ions in the c

275 and has resulted in a degree of control over electromagnetic fields that was previously impossible.

276 We demonstrated that by using nanostructured electromagnetic fields, the selection rules of absorptio

277 providing theoretical evidence that applying electromagnetic field therapy early on in the treatment

278 rapeutic ultrasound, acupuncture, and pulsed electromagnetic field therapy will be highlighted in thi

279 Owing to their highly localized electromagnetic fields, they may be used for the transpo

280 Possibly confined through its self-induced electromagnetic field, this plasmoid is shown to emit st

281 nteractions between electronic states, local electromagnetic fields (tip-induced plasmons), and molec

282 Plasmonic structures couple oscillating electromagnetic fields to conduction electrons in noble

283 remarkable ability to manipulate and control electromagnetic fields to produce effects such as perfec

284 ge from isolated nanoantennas with localized electromagnetic fields to symmetry-protected metasurface

285 ield-effect transistors (including realistic electromagnetic fields) to show that wavelength tunabili

286 Zero-point electromagnetic fields were first introduced to explain

287 thod captures atomic-scale variations of the electromagnetic fields while efficiently handling extrem

288 onal and rotational motions of molecules, an electromagnetic field with an appropriate frequency and

289 influenced the coupling of the LSPR-enhanced electromagnetic field with FM materials.

290 ticles resulting from strong coupling of the electromagnetic field with the lattice vibrations of pol

291 be possible to achieve imaging of evanescent electromagnetic fields with electron pulses when such fi

292 Through measurement of charged particles and electromagnetic fields with NASA's Magnetospheric Multis

293 eous distributions of DC and radio-frequency electromagnetic fields with optical fields that require

294 The strong interaction of electromagnetic fields with plasmonic nanomaterials offe

295 /2 particles undergoing Larmor precession in electromagnetic fields with small field non-uniformities

296 The interaction of static to high frequency electromagnetic fields with the cell constituents induce

297 Each natural mode of the electromagnetic field within a parabolic mirror exhibits

298 obtaining strong coupling between motion and electromagnetic fields without adding additional decoher

299 ynamically in response to the local incident electromagnetic field would provide a remarkable route t

300 currents from measurements of the associated electromagnetic fields would significantly benefit from