ライフサイエンスコーパス: electric field

1 s at the water-oil interface subjected to an electric field.

2 nt ionic concentrations without any external electric field.

3 orifice and is not dependent on the nanopore electric field.

4 cortical neuron orientation relative to the electric field.

5 eved in polymer nanocomposites at a moderate electric field.

6 a bacterium near collector surfaces in a DC electric field.

7 ermionic Hubbard chain subject to a constant electric field.

8 ids) based on application of the alternating electric field.

9 , followed by electrocoalescence using an AC electric field.

10 ical wormhole in the presence of an in-plane electric field.

11 ing to their net charge, when exposed to the electric field.

12 olution, revealing the fast-acting focussing electric field.

13 eq)) upon increasing strength of the applied electric field.

14 version symmetry by applying a perpendicular electric field.

15 ation without the application of an external electric field.

16 size free volume element and distinct local electric field.

17 rature under high-pressure and high external electric field.

18 nically deformed under the application of an electric field.

19 nsion of the ruptures first generated by the electric field.

20 tially mapped via its behavior in an applied electric field.

21 as its stability with respect to an external electric field.

22 onfining the fluid, via applying an external electric field.

23 en two electric dipole states by an external electric field.

24 ential mobility in an asymmetric oscillating electric field.

25 tor strength redistribution under a vertical electric field.

26 ymmetric drop shape analysis (ADSA) under an electric field.

27 rging and splitting using a perpendicular AC electric field.

28 ich organic phase is exposed to a DC uniform electric field.

29 s, a gap is present even without an external electric field.

30 s locally enhanced bond alignment under high electric field.

31 of environmental conditions, such as applied electric field.

32 dipolar interactions by means of an external electric field.

33 tions of phospholipid bilayers responding to electric fields.

34 stance states of spin-valve structures using electric fields.

35 sly observed in thin films and under applied electric fields.

36 ign sodium nitrite in the presence of modest electric fields.

37 ong-lived sample of polar molecules in large electric fields.

38 e judiciously reproduced by applied external electric fields.

39 lays pronounced ECE driven by relatively low electric fields.

40 conductance and re-orient in the presence of electric fields.

41 xhibit a mechanical response to out-of-plane electric fields.

42 Both electric field (0-150 mV cm(-1) ) and microfiber diamete

43 The OH extracts were obtained using Low electric field (496.0 V/cm) or Intermediate electric fie

44 As a result, controlling spin magnetism with electric fields-a longstanding technological goal in spi

45 an artificial lipid bilayer and applying an electric field across it, we are able to elucidate the p

46 In contrast, under forward bias, the electric field across the IDL is destroyed, substantiall

47 Moreover, we find that this electric field adjusts the orientation of its substrate

48 ernal means, such as charge transfer or high electric field, allows the conversion of the crystal str

49 at invokes the water network-dependent local electric field along the C-C bond that connects the head

50 Here we use an external electric field along with optical lattice confinement to

51 he highest EC temperature change at a modest electric field, along with high thermal stability within

52 centration gradient to induce a stable local electric field and achieve DNA concentration, making it

53 devices, and pave a way to control the local electric field and carrier concentration in van der Waal

54 These signals respond linearly to the electric field and display the basic kinetic features of

55 n electrokinetics, which require an external electric field and generally become ineffective in high

56 Despite this, the roles of electric field and Joule heating in the switching proces

57 icted that this symmetry breaking induces an electric field and leads to a wealth of novel properties

58 he catheter tip simultaneously create a weak electric field and measure the impedance, which changes

59 ered and catalyzed at room temperature by an electric field and monitored with scanning tunneling mic

60 f metal nanoparticles, enhancing the overall electric field and therefore resulting in an enhanced si

61 anoparticles gave rise to strongly localized electric fields and resulted in a broad absorption in th

62 s, they require the application of very high electric fields and thus their EC strengths DeltaS(EC) /

63 lectrolytic gating, which can generate large electric fields and voltage-driven ion transfer, has bee

64 e polymer, drive it into oscillation with an electric field, and image the oscillation with a near fi

65 ence of an alternating current (ac) external electric field, and their dielectric behavior can be exp

66 l still cameras, electric field meters, fast electric-field antenna systems, and for two seasons, a L

67 ns called "torons." Periodic oscillations of electric field applied perpendicular to the plane of hex

68 hin the soft matter medium in an oscillating electric field applied to a chiral liquid crystal with p

69 Pulsed electric fields are increasingly used in medicine to tra

70 rved as a strain-induced change in the local electric field around bubbles and creases, in agreement

71 One approach of interest to this work is the electric field assisted self-healing (eFASH) of open fau

72 ree-dimensional (3D) geometry by means of an electric-field-assisted additive manufacturing.

73 aqueous electrolyte solution in a four-phase electric-field-assisted extraction.

74 e core and shell regions leads to a built-in electric field at the heterojunction.

75 e are subsequently separated by the built-in electric field at the PN or NN heterojunctions, which re

76 ulations of the electrostatic potentials and electric fields at the site of the transferring protons

77 w of particle-free ambient air and a tunable electric field based on the respective particle electrop

78 Surface calculations showed that positive electric field between the NAD(H) binding sites on LDH a

79 molecular dipole, which is reoriented by the electric field between the tip and substrate.

80 waves (SAWs) or by microelectrode-generated electric fields, both at frequencies around 100 MHz.

81 rials in the human body are known to provide electric fields by pressure.

82 ons with EEF, and quantum mechanical/(local) electric field calculations.

83 The working mechanism is that an alternating electric field can be induced once contact-sliding occur

84 ACET flow induced by a biased AC electric field can rapidly convect the analyte onto nano

85 We show that electric fields can induce pores in the voltage-sensor d

86 Electric fields can transform materials with respect to

87 n, the electrophoretic operating conditions (electric field, capillary length, and internal diameter)

88 tage-sensing domains transduce transmembrane electric field changes by a common mechanism involving t

89 use models of drug-resistant focal epilepsy, electric-field changes in the brain associated with seiz

90 by directly measuring both the magnetic and electric field components of the EMF emitted by HVDC cab

91 ng the control parameter, i.e., the external electric field, conditions the nonequilibrium self-assem

92 data provides a clear evidence that moderate electric fields contribute to distinct folding/unfolding

93 This electric field control enables an alternate modality for

94 Electric field control of magnetism ultimately opens up

95 Here we experimentally demonstrate direct electric-field control of magnetic states in an orbital

96 electronic phase transformations through the electric-field controlled proton evolution with ionic li

97 We envision that electric-field controlled protonation opens up a pathway

98 d enable the exploration of twist-angle- and electric-field-controlled correlated phases of matter in

99 en identified as a powerful means to achieve electric-field-controlled phase transformations.

100 nsition metal oxide that shows a reversible, electric-field-controlled transformation between distinc

101 goal include material chirality, strain and electric-field controls.

102 The molecular mechanisms by which the electric field could affects these molecules remain unid

103 lier work indicated that direct current (DC) electric fields could influence bacterial deposition in

104 uring pulsed field ablation (PFA), subsecond electric fields create microscopic pores in cell membran

105 The method utilizes pulsed electric fields deforming the interface between an aqueo

106 ravity is dominant in the dripping mode, the electric field degenerates the electrospray mechanism in

107 t high dielectric permittivity (~1300), slim electric field-dependent polarization (P-E) curve with h

108 The large electric field developed across the molecular-scale ioni

109 onsistent with this hypothesis, we show that electric fields directly applied within the skin are suf

110 This effectively changes the electric field distribution around the tips of lithium b

111 However, strain and electric field do not appear to play any role in the ini

112 In contrast, an electric-field-driven magneto-electric storage element c

113 ductance switching is then attributed to the electric-field-driven reorientation of the individual di

114 Cluster formation in the alternating electric field during differential ion mobility is criti

115 In this study, the effects of moderate electric fields during thermal denaturation of beta-lact

116 e absolute mobility K at moderate normalized electric field E/N and field asymmetric waveform IMS (FA

117 For d > 14 nm, both dark and PC become electric field (E) dependent and exhibit approximate ove

118 netic resonance imaging (fMRI) and iterative electric-field (E-field) modeling in a generalized appro

119 Applying additional external electric fields (EEFs) induces a significant change to t

120 When and how do external electric fields (EEFs) lead to catalysis in the presence

121 ly evaluate the effects of oriented external electric fields (EEFs) on the same aza-Diels-Alder react

122 In a developing nervous system, endogenous electric field (EF) influence embryonic growth.

123 nally, we highlight how understanding of the electric fields effect on the EAS reaction could lead to

124 ntally viable strategy to implement external electric-field effects in routinely used oxidative addit

125 ther show evidence that salt additives exert electric-field effects on the rate of cross-coupling rea

126 ellular behavior within programmed stand-off electric fields (EFs) and monitoring cellular responses

127 tensity (up to and exceeding 6.5 V/cm pk-pk) electric fields (EFs) to cell and tissue cultures genera

128 the heating effects associated with the high electric fields employed.

129 lementary modelling of mass transport in the electric field, enables particle size to be estimated an

130 control of Taylor cone instability and micro-electric field, enables the creation of networks with ch

131 to the tip were studied based on the strong electric field enhancement along the tip.

132 s (NCs) have attracted much attention due to electric field enhancements at their tips.

133 hese results provide direct insight into the electric field environment at the Pt surface and highlig

134 We show how electric fields exerted by the insulating substrate may

135 Cellular effects of nanosecond-pulsed electric field exposures can be attenuated by an electri

136 cells capable of detecting subtle changes in electric fields (Figure 1B) [3,4].

137 agnetic response of the fibers to an applied electric field, FMR measurements were done on a single f

138 ets are manipulated for the first time by an electric field for controlling organic reactions.

139 vdW heterostructure with a vertical built-in electric field for high-efficiency broadband light absor

140 e-entrant Mott insulator with the increasing electric field for phonon density of states that increas

141 enomena and for gate-tunable built-in planar electric fields for device applications.

142 ce that exists due to the considerable inner electric field force at the nanoscale.

143 se peroxide formation is induced by a strong electric field formed at the water-air interface of micr

144 through direct host-guest interactions, the electric fields from the nanocage also supports the tran

145 rajectory during aging by characterizing the electric field generated by cortical dipoles using reali

146 ts are tuned by exposing the qubit sample to electric fields generated by electrodes surrounding the

147 NU-1000 can also be dynamically aligned via electric fields, giving rise to rapid electrooptical res

148 Owing to the sharp edge-enhanced electric field, gold triangular nanoplates (AuNPLs) exhi

149 e cars are designed to be stimulated with an electric field gradient from a scanning probe microscopy

150 The ions are guided through an internal electric field gradient of the FmuTP that arises from ch

151 We achieve an appropriate electric field gradient using a selective ionic focusing

152 81)Br and (127)I) combined with the enhanced electric field gradients around these nuclei existing in

153 We discovered that electric field gradients can be used to control and acce

154 Electric fields greater than 129 Td or new designs of re

155 ivity (E(F)-B(z)-sigma(xy)) and Fermi energy-electric field-Hall conductivity (E(F)-E(z)-sigma(xy)) p

156 Weak electric field has anti-biofilm properties.

157 The electric field has been found to affect tissue developme

158 tic order in magnetoelectric Cr(2)O(3) using electric field has been of great interest due to its pot

159 Electric fields have been used with great success to sel

160 ble ability of the ionomer coating to enable electric field homogenization over a considerably large

161 of these reactions, which generate a strong electric field, hot carriers, and heat through the excit

162 conjunction with reconstruction of the local electric field, identify the negative capacitance region

163 electric field (496.0 V/cm) or Intermediate electric field - IEF (840.0 V/cm).

164 ng by ferromagnetic resonance (FMR) under an electric field in a coaxial nanofiber of nickel ferrite

165 rodynamics to emphasize the dominance of the electric field in dynamic light-matter interactions that

166 work provides evidence that the active site electric field in KSI is preorganized to facilitate cata

167 The creation of a reverse electric field in surface layers effectively restrains t

168 The built-in electric field in the depletion region induces polar str

169 l thickness in order to analyse the built-in electric field in the GaN channel layer.

170 f a transverse heat current upon applying an electric field in the presence of a magnetic field.

171 ectron band that is tunable by perpendicular electric fields in a range of twist angles.

172 Results have shown that the effects of electric fields in protein unfolding were linearly depen

173 phase coexistence and response under applied electric fields in superlattices of (PbTiO(3))(n)/(SrTiO

174 lations that magnetic stimulation can induce electric fields in the pigeon semicircular canals that a

175 A strong induced electric field, in the process, penetrates through the n

176 hotocurrent distributions are independent of electric field, indicating that photoexcited electrons a

177 A piezoelectric substrate transfers electric field induced strain to adjacent magnetic layer

178 (3,4) from ferromagnetic (FM) monolayers and electric-field induced Kerr rotation(5-7) and giant seco

179 MD simulations, the kinetics of ultrashort, electric-field-induced permeabilization of GUVs were sig

180 Furthermore, it is found that the electric-field-induced phase transition spreads over a l

181 ic, which we use to demonstrate non-volatile electric-field-induced reversal of the magnetic state.

182 cle suspensions, a high-magnitude DC uniform electric field induces nonlinear particle velocities, le

183 ips among ion fluxes, between water flow and electric field inside cells, and in the narrow extracell

184 effect (VSE) spectroscopy, we have measured electric fields inside the active site of the enzyme ket

185 e membranes enable the generation of uniform electric fields inside the droplets, while simultaneousl

186 eaching from the cells subject to increasing electric field intensities with subsequent reuptake conf

187 position and the corresponding standing-wave electric-field intensities within the layer structure.

188 lding were linearly dependent on the applied electric field intensity (V/cm) and increased by the use

189 mechanism based on an adiabatically changing electric field interacting with the rotational structure

190 ical outward-directed topology of the sheath electric field into a focusing configuration.

191 However, in the presence of electric fields, ionisation spectra exhibit frequency sh

192 s work reports on the application of a novel electric field-ionization setup for high-resolution lase

193 The electric field is also strongly concentrated in the gaps

194 A substantial ~10 MV cm(-1) electric field is created by electron injection into TiO

195 For reversible EP, precise control over the electric field is critical to regulate the induced pore

196 tional modeling to show that KSI's intrinsic electric field is nearly perfectly oriented to stabilize

197 the spatial distribution of the longitudinal electric field is reported and excellent agreement with

198 ilayer phosphorene, a composite magnetic and electric field is shown to induce a feature-rich Landau

199 Electrical treeing caused by high, local electric fields is a damaging process that leads to stru

200 le electroporation (EP) using high intensity electric fields is a simple means of transfection applic

201 cancies in NdNiO(3) can be controlled via an electric field, leading to analog resistance switching b

202 amage-free exposure of dielectrics to strong electric fields, leading to reversible switching between

203 s can be mimicked by use of (designed) local-electric fields (LEFs), i.e., by embedding charges or di

204 everal decades of research suggest that weak electric fields may influence neural processing, includi

205 ndard-speed video and digital still cameras, electric field meters, fast electric-field antenna syste

206 ultaneous use of pressure-driven flow and DC electric field, migration of particles inside microfluid

207 ace in different VGICs when exposing them to electric fields mimicking electroporation conditions.

208 stributions near hydrophobic interfaces, and electric fields near the surface of water droplets.

209 s and insulators, and as a result, substrate electric fields need always be considered.

210 etectors demonstrates low dark current under electric fields needed for high sensitivity X-ray imagin

211 Nanosecond pulsed electric fields (nsPEF) have been shown to efficiently a

212 Nanosecond Pulsed Electric Fields (nsPEF) have the potential to treat a va

213 This Perspective discusses oriented external-electric-fields (OEEF), and other electric-field types,

214 Judiciously applied oriented external electric fields (OEEFs) exert catalytic effects on the k

215 ~0.22 K m MV(-1) is obtained at an ultralow electric field of 75 MV m(-1) in nanocomposites filled w

216 The electric field of light striking a metal interacts with

217 ion of the structure and response to applied electric field of the lower-temperature nematic phase of

218 ous interfacial electrostatic potentials and electric fields of GCC organic acids are computed as fun

219 ectroscopy (SERS) which utilizes oscillating electric fields of metal nanoparticles, enhancing the ov

220 transient Stark effect, caused by nanoscale electric fields of ~487 kV/cm between photogenerated fre

221 s the production, upon the application of an electric field, of a transverse voltage under an out-of-

222 By applying an electric field on the crystal surface, the linear EO eff

223 d the ability to manipulate this entity with electric field on the nanoscale expand the existing phen

224 ial to explore the stimulatory influences of electric fields on cellular processes in tissue and rege

225 resistance can be hysteretically switched by electric field or current are intensely pursued both for

226 o-noise ratio (SNR) scales linearly with the electric field over those whose SNR scales linearly with

227 s study investigated the potential of pulsed electric field (PEF) as a sodium-reduction strategy for

228 Pacific white shrimp with prior pulsed electric field (PEF) treatment before soaking in Chamuan

229 The effect of high pressure (HP) and pulsed electric field (PEF) treatments combined or not with hea

230 current (ac) conduction under an excitation electric field perpendicular to the surface.

231 Our results reveal that components of the electric field perpendicular to the tip should be consid

232 Simultaneous imaging of the electric field, phase, annular dark field and the total

233 r is confined to a small area in the density-electric-field plane, and is attributed to a phase trans

234 the Menshutkin species and induces a global electric field pointing in the opposite direction of the

235 concentrations of H(+) and OH(-), and local electric field polarization of a MgO (111) support durin

236 rease in the response time after an external electric field poling.

237 ior is attributed to a combination of strong electric fields present at the aqueous-silica interface

238 ntal challenges like poor stability under an electric field prevent realistic applications of halide

239 r (bio)-technological applications involving electric fields processing, bringing new insights for th

240 e (123)Sb (spin-7/2) nucleus using localized electric fields produced within a silicon nanoelectronic

241 e simultaneous focusing and squeezing of the electric field produces strong 'doubly-enhanced' hotspot

242 ar-field optical microscopy we visualize the electric field profiles of waveguide modes in real space

243 application of high amplitude short length electric field pulses.

244 The electric-field-responsive contrast agent may increase th

245 tric field exposures can be attenuated by an electric field reversal, a phenomenon called bipolar pul

246 the data suggest that the externally applied electric field significantly stimulates the mass-transfe

247 tion does not increase monotonously with the electric field strength above an optimum E(0), which is

248 by three orders of magnitude as we tuned the electric field strength by a few percent across resonanc

249 oltage to several volts to induce sufficient electric field strength for efficient bacteria inactivat

250 owing through different outlets to different electric field strength, thus resulting in different imp

251 varying electrolyte concentrations and weak electric field strengths (0-2 V cm(-1)).

252 The EEG changes correlated with electric fields strengths in prefrontal cortices, and no

253 ications, for example treating problems with electric fields, such as electrosprays.

254 ments of adsorption at an interface under an electric field suggest that the optimum E(0) is determin

255 in cells exposed to ultrashort (6 and 2 ns) electric fields, suggesting that cellular electroporatio

256 ersing the direction of the applied vertical electric field switches the moire minibands of ABC-TLG/h

257 also known as memristor(1) effect, where an electric field switches the resistance states of a two-t

258 resistance hysteresis by magnetic field and electric-field switching of magnetization even in multil

259 array/perovskite system exhibits an oriented electric field that can increase charge separation and a

260 lectric effect produces the surface positive electric field that exhibits electrostatic attraction to

261 Here we show that a built-in electric field that originates from band bending at hete

262 We propose that the enhanced local electric field that results from the localized surface p

263 This surface charge generates an electric field that serves to recruit extrinsic cationic

264 in the context of fluctuations in the local electric fields that are available even at low temperatu

265 hat an encapsulated water molecule generates electric fields that contributes the most to the reducti

266 the interfacial water, which in turn creates electric fields that misalign with the breaking bonds of

267 Internal electric fields that underpin functioning of multi-compo

268 operating principle of rf ion traps requires electric fields that vary in space and time.

269 Upon application of an electric field, the cell membrane is compromised, allowi

270 dependence between frequency of the applied electric field, the intensity of the surface enhanced Ra

271 nce photoinduced phenomena such as localized electric fields, therefore-they have been used in variou

272 ble for pure electrical switches; under weak electric fields, they show extremely low conductivity, w

273 d shells that deform upon the application of electric fields; they excel among soft actuators with mu

274 rate of decay implies a sufficiently strong electric field to account for the particle acceleration

275 s illuminated with light and an applied a.c. electric field to create the spatially varying electrohy

276 imple method of using an alternating-current electric field to engineer the domain structures of orig

277 ar-field enhancements could help confine the electric field to the electrodes.

278 which is self-powered to provide an internal electric field to the few-layered MoS(2) nanosheets surr

279 tunability (> 100%) is achieved with applied electric field to the PMN-PT [011] substrate.

280 amagnetic resonance (EPR) spectroscopy under electric fields to assess their magnetoelectric (ME) cou

281 nowire-modified electrodes, locally enhanced electric field treatment (LEEFT) reduces the required vo

282 Electric field treatment inactivates bacteria by physica

283 overy of spin-polarized correlated states in electric-field-tunable TDBG provides a new route to engi

284 e has been proposed in this work with strong electric field tuning of magnetism.

285 d external-electric-fields (OEEF), and other electric-field types, as "smart reagents", which enable

286 changes in the magnitude of the interfacial electric field under the conditions of H(2)/H(+) catalys

287 f theta generate large gate-tunable in-plane electric fields, unscreened even in the metallic regions

288 f the orthogonal components of the terahertz electric field vector without cross-talk.

289 emissions have been observed in snapshots of electric field waveforms.

290 Thanks to the application of the electric field, we improve SERS technique by decrease of

291 ctivity through variations of the energizing electric field, we reveal emergent dynamic phases, rangi

292 In the presence of a strong 0.4-0.8 MV/cm electric field, well-resolved transitions are observed f

293 nearly increases with increasing the applied electric field, where the Rashba coefficient in (BA)(2)(

294 ally conducted in low and highly homogeneous electric fields, whereas the operating principle of rf i

295 nsmission or gap junctions, but can generate electric fields which in turn activate neighbouring cell

296 lay an inhomogeneous distribution of PZC and electric field, which directly affects the electrochemic

297 results show that a 0.2 V/ angstrom external electric field, which is below the threshold for bond br

298 ma-K interlayer excitons can be flipped with electric fields, while higher-energy K-K interlayer exci

299 ins is then driven by the interaction of the electric field with the polarity of domain boundaries.

300 Control via electric fields would resolve this problem, but previous