ライフサイエンスコーパス: interfacial

1 The interfacial 1T-MoS(2)-C(60) and C(60)-C(60) interactions

2 contribute to understanding the mechanism of interfacial activation and inhibition for Lp-PLA(2) and

3 Oils with higher interfacial activity are found to respond more positivel

4 rogeneity of these systems, interrogation of interfacial activity at nanometer length scales is desir

5 , we further tested the hypothesis that such interfacial activity is a correlate of broad-spectrum an

6 The interfacial activity of JNPs can be further tuned by com

7 Interfacial adhesion energy is a fundamental property of

8 relationship of DOPA and Lys as well as the interfacial adhesive roles of other amino acids have bee

9 The interfacial aggregation of hydrogen is controlled and qu

10 and kinetic parameters, e.g., the effective interfacial (alpha') and apparent activation (E(a)) ener

11 d hydrogen bonds with the water molecules in interfacial and bulk environments, respectively.

12 uch a wide frequency range and includes both interfacial and polarization effects in this simple form

13 scattering is used for tracking solid-state, interfacial, and near-field-driven chemical reactions oc

14 e behavior of [Au(CH(3))(2))](-) in bulk and interfacial aqueous environments.

15 mulsification resulted in an increase of the interfacial area and hence a higher conversion.

16 e is likely to be absent or occupy a minimal interfacial area.

17 cells containing resistive organic media and interfacial areas in the cm(2) and mm(2) range.

18 model exhibit native-like features including interfacial aromatic side chains, hydrophobic lengths co

19 However, the exact role of interfacial atomic structures in governing catalytic pro

20 tational analysis also reveals a distinctive interfacial behavior in transition metal dichalcogenides

21 we expand current options to investigate the interfacial behavior of food proteins by determination o

22 The unique interfacial between the Zn marigold flower layer as low

23 ve resistance to MEK inhibition by enhancing interfacial binding.

24 nd to be orders of magnitude slower when the interfacial bonds with the heteroepitaxial substrate are

25 ediates and catalyst material across surface interfacial boundaries in alloys with a significant effe

26 Membrane-bound oligosaccharides form the interfacial boundary between the cell and its environmen

27 d electricity, and salt concentration of the interfacial buffer.

28 The sensing strategy directly measured the interfacial capacitance whose change rate was adopted as

29 band energy alignment and concerted cascade interfacial carrier extraction, rendered by concurrent p

30 lar cells (PSCs) and, in turn, to impact the interfacial carrier injection and recombination processe

31 ring emulsions are an excellent platform for interfacial catalysis.

32 nt progress and approaches to understand the interfacial challenges via advanced characterization tec

33 ce (QCM) were respectively employed to probe interfacial characteristics of fibronectin fragment FNII

34 doping is an effective route to control the interfacial charge recombination in perovskite solar cel

35 This largely reduced the interfacial charge recombination loss and achieved a rec

36 This is mainly due to severe interfacial charge recombination occurring at the transp

37 itates electron tunneling and suppresses the interfacial charge recombination.

38 that promotes the migration of electrons and interfacial charge separation.

39 of energy conversion due to their excellent interfacial charge states in tuning the electronic prope

40 The limited oxidative stability and poor interfacial charge transport in conventional polymer ele

41 rated by thermally activated dissociation of interfacial charge-transfer states that occurs over hund

42 tovoltage owing to the low driving force for interfacial charge-transfer.

43 form solid-state polymer batteries with good interfacial charge-transport properties.

44 The interfacial chemical reaction between nylon and MAHgEO g

45 The interfacial chemical reactivity of Jahn-Teller-active tr

46 ows of nonaqueous solutions, and the complex interfacial chemistry remains elusive.

47 n was revealed to be concentration-dependent interfacial chemistry that only occurs among closely con

48 the basis of improved wetting and stabilized interfacial chemistry, such liquid metal batteries deliv

49 nance (NMR) spectroscopy is sensitive to the interfacial chemistry, the phase purity including the pr

50 e chemical heterogeneity to govern the local interfacial chemistry.

51 This extension of interfacial complex formation beyond metal elements open

52 ar effectors are secreted via the biotrophic interfacial complex, translocated into the nuclei of ini

53 t that, increasing the oil phase volume, the interfacial concentration decreased for the more lipophi

54 A critical interfacial concentration of 0.20-0.31 wt% beta-lactoglo

55 study was the determination of the critical interfacial concentration of whey protein beta-lactoglob

56 netics are not only impacted by the physical interfacial contact but are also closely associated with

57 s used to predict the effects of pressure on interfacial contact in the multilayered structures of PS

58 The regulation of the interfacial contact to the attached skin confines the pr

59 In spite of the initial discrete interfacial contact, solid-state batteries may still dis

60 n activity by optimizing F-actin-tropomyosin interfacial contacts and by binding to actin, which rest

61 ty may be required to establish and maintain interfacial contacts with tropomyosin as well as facilit

62 iscriminating genuine molecular effects from interfacial contributions.

63 y, high resolution, and high throughput, the interfacial convective assembly opens remarkable opportu

64 Here, a chemical mapping of the interfacial coupling between the nanofiller and the poly

65 The interfacial coupling induced Dzyaloshinskii-Moriya inter

66 etween WSe(2) and CrI(3) is dominated by the interfacial CrI(3) layer, while the proximity exchange f

67 neous hydrogels can be structurally fused by interfacial crosslinking and coupled as input and output

68 se transitions and the role of the droplets' interfacial curvature in inducing these transitions rema

69 ne halide perovskite thin films with minimum interfacial damage and an atomically clean interface.

70 in we investigated LiTFSI/H(2) O electrolyte interfacial decomposition pathways in the "water-in-salt

71 zed to be the mechanism for reduction of the interfacial defects.

72 tively weak against crack propagation due to interfacial delamination, which substantially increases

73 er the respiratory air-liquid interface: the interfacial delivery.

74 an intrinsic spin-orbit coupling generating interfacial DMI at mirror symmetry-breaking interfaces.

75 Our work opens new paths for controlling interfacial DMI in ferrimagnets to nucleate and manipula

76 romagnet case, few studies have investigated interfacial DMI in ferrimagnets.

77 ulators (TIs) is utilized to provide a large interfacial DMI in TI/ferrimagnet heterostructures at ro

78 t gaining experimental information about the interfacial dynamics of water in fields such as catalysi

79 ts into the configurational disorder-induced interfacial effect and will enable rational design and m

80 structural evidence to support the so-called interfacial effect in dielectric nanocomposites.

81 trical system, transforming the conventional interfacial effect into a bulk effect, and so enhancing

82 The interfacial effect leads to significant changes in the m

83 e metre, owing to the limitations imposed by interfacial effects-as seen in characterizations of the

84 over equivalent devices that are limited by interfacial effects.

85 Au/TiO(2) interface significantly alters the interfacial electron distribution and prompts O(2) activ

86 k and are able to dramatically influence the interfacial electron transfer and adsorption of chemical

87 In contrast, interfacial electron transfer in PFE is fast, lifting th

88 Here, we report the interfacial electron transfer kinetics for molecules pos

89 lent iodine intermediates effectively couple interfacial electron transfer with oxidative C-H/N-H cou

90 The total reorganization energy, lambda, for interfacial electron transfer, ET, from a conductive ele

91 antly reduces the Coulomb attraction between interfacial electron-hole pairs.

92 nic acid moieties, PCET is driven by complex interfacial electrostatic and field gradients that are d

93 molecular probe of the heterogeneity of the interfacial electrostatic potential at the alpha-Al(2)O(

94 Herein, the spatially inhomogeneous interfacial electrostatic potentials and electric fields

95 the atomic structure of the surface and the interfacial electrostatic potentials and fields that gov

96 Moreover, we establish the influence of the interfacial energetics on the electron and hole transfer

97 m a solid electrolyte interphase with a high interfacial energy and self-healing capabilities, develo

98 is activated and injection limited due to an interfacial energy barrier much larger than that for bul

99 deriving it from the favorable alignment of interfacial energy levels of DMASnBr(3) and g-C(3) N(4)

100 eld exerted by the substrate to minimize the interfacial energy of the system.

101 generate an electrostatic landscape with an interfacial energy offset of 0.4 eV, which promotes the

102 The robust LiF-enriched SEI with high interfacial energy to Li metal effectively promotes plan

103 composition and attempt to relate it to the interfacial energy.

104 Investigation into interfacial engineering further reveals enhanced light a

105 but also sheds light on further surface and interfacial engineering of advanced hybrid materials.

106 es, as well as new strategies for host-guest interfacial engineering.

107 that lateral and temporal inhomogeneities of interfacial environments are important for fully charact

108 archers in building better kinetic model for interfacial enzymes.

109 by our group, which allows investigation of interfacial events by performing surface-sensitive and l

110 an give a fatigue-resistant adhesion with an interfacial fatigue threshold of 800 J m(-2), because th

111 the GCC acid site and the graphite to enable interfacial field-driven PCET at the acid site.

112 the dipole of *CO[Formula: see text] and the interfacial field.

113 rfactant density, they are expelled from the interfacial film at high surfactant density.

114 nterface generates a surface pressure-driven interfacial flow (Marangoni flow) that causes transient

115 ing facile exfoliation due to the absence of interfacial forces as a nonpolar liquid.

116 st molecular scale study of the decay of the interfacial friction force in rock, observed in experiem

117 mic structural slc13 model suggested that an interfacial helix, H4c, which is common to all slc13s, s

118 Zn layer decorated by n-type dichalcogenides interfacial heterojunction was successfully designed and

119 This is ascribed to the interfacial hybridization between the Ti3d-orbitals of t

120 study of charge localization in cuprates and interfacial hybridization provides important clues to th

121 Notwithstanding the interfacial hydrated proton exhibiting bulk-like structu

122 n, surface-solvent-ion correlations, and the interfacial hydrogen bonding environment.

123 ness with convenience and exceptionally high interfacial impedimetric baseline stability.

124 e is identified where intermittent cascading interfacial instabilities appear.

125 Both techniques reveal strong interfacial interaction between the antiferromagnetic or

126 dynamics simulations reveal the synergistic interfacial interaction mechanisms of Ti-O-C covalent bo

127 The model incorporates both the interfacial interactions of the suspension with the elec

128 tions enhance channel activity by disrupting interfacial interactions.

129 The interfacial interconversion of H(6) TPPS, specifically H

130 al nanoscale electrokinetic study as well as interfacial ion transportation between liquid and plasma

131 efects/pores on interface and homogenize the interfacial ionic/electronic flux, facilitating the redu

132 s architecture faces challenges arising from interfacial issues between the electrode and solid elect

133 Interfacial issues commonly exist in solid-state batteri

134 es of liquids into targeted architectures by interfacial jamming of nanoparticles is an emerging area

135 his resulted in color-tunable liquids due to interfacial jamming of the SPSs formed between H(4) TPPS

136 ombination with the intimate Li(x)NiO and Ni interfacial junctions that generate localized hotspots f

137 Depletion of Ge from the interfacial layer (IL) by enhancement of volatile GeO(x)

138 e introduced EC-GC10 encapsulated perovskite interfacial layer at the perovskite/HTM interface helps

139 The use of C(60) as an interfacial layer between TiO(2) and methylammonium lead

140 stable, atomically thick CuCr(1-x)Al(x)O(2) interfacial layer is the critical element for the epitax

141 In addition, the composition of the interfacial layer was dependent on the composition of th

142 The interfacial layer was predominantly covered by the CN an

143 er protein surface load leading to a thicker interfacial layer, lower formation of hexanal, (E)-2-hex

144 f WPI content reduced the viscoelasticity of interfacial layers (LCT/MCT-1% WPI).

145 by mainly limiting the open circuit voltage, interfacial layers are also crucial.

146 ceptor gating takes place in the ECD and the interfacial M2-M3 linker but fails to penetrate the memb

147 a way to control proximity effects and probe interfacial magnetic order via van der Waals engineering

148 This provides an additional interfacial mechanism for the catalytic and plasmonic en

149 Overall, we hope our analytical insights on interfacial mechanisms will help in gaining a wider acce

150 ies arise from the relative strengths of the interfacial metal-chalcogen bonds during the reduction o

151 The acidity of their interfacial (micro)environment depends on the bacterial

152 We report herein a voltage-controlled interfacial microreactor that enables acceleration of el

153 ctions by voltage-dependent formation of the interfacial microreactor; ii) "reversible" electrochemic

154 Understanding the interfacial molecular structure of acidic aqueous soluti

155 t of the PS film, which likely results in an interfacial monolayer enriched in dipalmitoylphosphatidy

156 that the adsorbed PS film is composed of an interfacial monolayer, plus a functionally attached vesi

157 The DMI thickness dependence confirms its interfacial nature.

158 xcellent platform for the rational design of interfacial oxide architectures to precisely create, con

159 architecture designed to create high-density interfacial oxygen vacancies.

160 ur findings underscore the importance of the interfacial oxygen vacancy migration and redistribution

161 (MIT) in oxide heterostructures by inducing interfacial oxygen vacancy migration.

162 hnologies, but molecular-level insights into interfacial PCET are limited.

163 At carbon surfaces, designer sites for interfacial PCET can be incorporated by conjugating orga

164 it points toward the interface to facilitate interfacial PCET with Y356, and a stacked conformation w

165 te biological scale experiments, and several interfacial peptides.

166 Due to the improved interfacial performance, the inhibitory effect of the an

167 methanol-production at the copper-zinc oxide interfacial perimeter of copper/zinc oxide/alumina (CZA)

168 eraction between the reconstructed Au(4)S(4) interfacial phase and TMD monolayers results in the tran

169 report the epitaxial stabilization of a new interfacial phase formed during pulsed-laser epitaxy of

170 with the formation of a metastable Au(4)S(4) interfacial phase which is stabilized by the top MoS(2)

171 s of the equilibrated materials yielding the interfacial phases U(20)Si(16)C(3), U(3)Si(5) and UC rev

172 ies (e.g., surface charge and potential) and interfacial phenomena (e.g., particle adhesion) become t

173 From an interfacial phenomena standpoint, gallic acid (GA), meth

174 n alternative analytical approach to monitor interfacial phenomena using EW-CRDS technique.

175 optical filtering effect resulting from the interfacial polar alignment between monolayer MoS(2) and

176 structs, which include the dipole moment and interfacial polarizability.

177 nes formed via surfactant-assembly regulated interfacial polymerization (SARIP).

178 working mechanisms of different surface and interfacial polymerization and the current challenges an

179 We utilize layered interfacial polymerization to prepare physically and che

180 ers across the water/hexane interface during interfacial polymerization, thereby forming a polyamide

181 es compared to those formed via conventional interfacial polymerization.

182 By measuring a time series of interfacial positions and computing the average power sp

183 The interfacial potential contribution to the free energy re

184 w material phases (interphases) regulate all interfacial processes at a Li metal anode, including ele

185 NFS may explain other important interfacial processes involving silica particles.

186 act with solid-water interfaces, macroscopic interfacial properties (e.g., surface charge and potenti

187 on this theory, we measure otherwise elusive interfacial properties such as interfacial stiffness and

188 Many biological processes are based on interfacial protein action, ranging from cellular commun

189 entration while the increase was observed in interfacial protein concentration ( ).

190 hods that has made it possible to also study interfacial proteins and their folding, binding, orienta

191 Then we give an extensive overview of the interfacial proteins studied to date with SFG.

192 Despite the importance of interfacial proteins, comparatively little is known abou

193 ns at the water-air interface and reveal the interfacial proton continuum.

194 The hydration of the interfacial proton is necessarily different from that in

195 Interfacial proton-coupled electron transfer (PCET) reac

196 ional spectroscopy, we probe the response of interfacial protons at the water-air interface and revea

197 rmed to measure the activation energy of the interfacial reaction, enabling a comparison with that re

198 ickness beyond which the otherwise sustained interfacial reactions are arrested.

199 simulation, we reveal that the cathode-water interfacial reactions can lead to the surface passivatio

200 Indeed, the features of interfacial reactions differ, often drastically, from th

201 , understanding of the nature of cathode-air interfacial reactions remain elusive.

202 e, removing the driving force for additional interfacial reactions.

203 We introduce two design guidelines, based on interfacial reactivity and crystal structure relations,

204 graphene electrodes enable the modulation of interfacial reactivity by means of underlying substrate

205 main contributor to the observed changes in interfacial reactivity upon illumination.

206 Here we report the interfacial reconstruction between TMD monolayers and go

207 The interfacial reducibility and structure of composite cata

208 f SPR as a result of the modification of the interfacial refractive index profile by surface adsorpti

209 ent cation (calcium) distribution within the interfacial region and reduces the energetic burden of c

210 s may include the Pt/gamma-Al(2)O(3) surface interfacial region as one component of a heterogeneous c

211 Furthermore, the interfacial region includes selected residues from an in

212 lybasic peptide partitions into the membrane interfacial region with an affinity and a lipid binding

213 ity, local structure, and wettability of the interfacial region.

214 with the concentration of antioxidant at the interfacial region.

215 of the solvation environment in the bilayer interfacial region.

216 articularly steep as it crosses the membrane interfacial regions where the water concentration drops

217 ine and arginine side chains in the membrane interfacial regions, and lipid anchoring of the G protei

218 formation of highly polar and inhomogeneous interfacial regions, which is further enhanced with a de

219 Vbeta/Valpha, Vbeta/Cbeta, and Cbeta/Calpha interfacial regions.

220 g interactions and conformational motions of interfacial residues along the PCET pathway.

221 By modeling the interfacial resistance and capacitance using equivalent

222 5) Ta(0.25) O(12) (LLZTO) suffers from large interfacial resistance and severe Li-metal penetration.

223 ectronic flux, facilitating the reduction of interfacial resistance and suppression of dendrites.

224 e Li(3) PO(4) (LPO) dramatically reduces the interfacial resistance to ~1 Omega cm(2) and achieves a

225 e composite electrolytes demonstrate a small interfacial resistance with good cycling performance at

226 Current efforts mainly aim to reduce the interfacial resistance, neglecting the intrinsic dendrit

227 heir multiphase structure leads to a complex interfacial rheology, yet a detailed, microscopic unders

228 To address this challenge, a viscous interfacial self-assembly approach, to generate a bioins

229 sed as an artificial neutrophil by enzymatic interfacial self-assembly of peptides (Fmoc-Tyr(H(2) PO(

230 as-obtained composites not only promotes the interfacial shear stress to a high level and thus result

231 Our results can be interpreted as an interfacial shear thinning of the polymers with an incre

232 s proteins, as reflected by an increased A-W interfacial shear viscosity of the adsorbed film upon de

233 omain (TMD) housing the Zn(2+) substrate; an interfacial site between TMD and C-terminal domain (CTD)

234 The interfacial site is selective for sodium over other cati

235 under ambient conditions due to the enhanced interfacial stability to the Li metal anode.

236 it their practical application, such as poor interfacial stability, scalability challenges and produc

237 hibiting bulk-like structures, a substantial interfacial stabilization by -1.3 +/- 0.2 kcal/mol is ob

238 x assembly and regulation, identify a unique interfacial stabilizing mode of action for therapeutic t

239 was recently proposed to distinguish between interfacial states that differ in any equilibrium thermo

240 rwise elusive interfacial properties such as interfacial stiffness and mobility, the former of which

241 computing the average power spectrum, their interfacial stiffness was determined according to the ca

242 he incoming band, preventing the build-up of interfacial stresses.

243 th minimal perturbations to surfactant-water interfacial structure.

244 the Ag(78) NC, forming diverse metal-ligand interfacial structures.

245 of pressures to the devices to improve their interfacial surface contacts.

246 attering from defects, grain boundaries, and interfacial/surface roughness in the composite transduce

247 the 2DEG at a bare oxide surface (instead of interfacial system) by using both light and ferroelectri

248 sms driven by charge, spin, and lattice, the interfacial tailoring effect is solely mediated by the p

249 e molecular simulations indicate that as the interfacial temperature increases, bonds between the ato

250 o relax, hence contributing to the increased interfacial temperature.

251 vident from the growing decay in equilibrium interfacial tension (gamma(eq)) and increased surface ex

252 The role of the interfacial tension (IFT) and wettability in the microfl

253 and nanoparticles and reduced the oil/brine interfacial tension (IFT) from 14.6 to 5.5 mN/m.

254 c technique developed in our lab, Sorting by Interfacial Tension (SIFT), to isolate cancer cell subpo

255 unique synergy is achieved that is driven by interfacial tension and geometry: the adherent rGO under

256 te to form stable jets since it has enormous interfacial tension and low viscosity.

257 ing processes due to their ability to reduce interfacial tension between ink solvents and nanoparticl

258 presents measurements of air- and NAPL-water interfacial tension for synthetic groundwater containing

259 s found to positively correlate with the oil interfacial tension in low-salinity water.

260 Equations based on interfacial tension measurements show that concentration

261 The beta-carotene reduced the interfacial tension of the LCT/MCT-water systems.

262 The ability to tune interfacial tension over at least three orders of magnit

263 transiently at higher fluid velocities, yet interfacial tension rapidly drives jet breakup into drop

264 formulations were less efficient at lowering interfacial tension than PFOA, FPOS, or FOSA substances

265 The estimates of dynamic interfacial tension under different strengths of the fie

266 ard competition between chain stretching and interfacial tension under the constraint of filling spac

267 Interfacial tension which was affected by the solute con

268 d in terms of their acidity, zeta potential, interfacial tension, microdispersion propensity, water-s

269 ta and greater correlation to viscosity than interfacial tension.

270 nolayer at the water-oil interface to reduce interfacial tension.

271 transition in multiphase droplets using the interfacial tensions and critical salt concentration as

272 avorable for recovering oil, despite greater interfacial tensions, due to wettability alteration towa

273 Moreover, unlike the size-dependent interfacial thermal conductance at the interface between

274 kingly, that under realistic conditions, the interfacial topological modes are delocalised over many

275 rucial insights into underlying mechanism in interfacial transport.

276 e, water, and non-toxic alkanes formed by an interfacial trapping method in which graphite spontaneou

277 We investigate the structure of interfacial turbulence and its relation to the turbulenc

278 electrons from Ti(3+) species are trapped by interfacial V(o) on TiO(2) and hardly interact with peri

279 nation releases those trapped electrons from interfacial V(o) to facilitate O(2) activation.

280 surface-specific spectroscopy, we report the interfacial vibrational dynamics of ice I(h).

281 ding interactions of both Y731 and Y356 with interfacial water and hydrogen-bonded water chains appea

282 This drives an initially inhomogeneous interfacial water coordination landscape observed at the

283 measure the effect of oil phase viscosity on interfacial water dynamics in reverse micelles.

284 concentrations and kinetic barriers towards interfacial water electrolysis significantly expand the

285 of the bioadhesive relies on the removal of interfacial water from the tissue surface, followed by p

286 by monitoring the degree of alignment of the interfacial water molecules and the corresponding ice nu

287 1 exhibit hydrogen-bonding interactions with interfacial water molecules and, in some conformations,

288 s an external solvent instead of ML or n-Hp, interfacial water molecules have larger nucleophilicity

289 plex does not exhibit any proton loss to the interfacial water molecules.

290 These interactions distort interfacial water orientations and prevent hydrogen bond

291 on suggest that thiocyanate species organize interfacial water similarly to halide ions.

292 organization of the uranyl-ion hydration and interfacial water structures upon U(VI) adsorption at th

293 in the trans state, the methyl group repels interfacial water to maintain the planarity of the molec

294 the number of hydrogen bonds between MG and interfacial water while minimizing the torsional free en

295 CO-terminated tip (used previously to image interfacial water with minimal perturbation)(12), enable

296 to examine the structure and fluctuations of interfacial water, as well as the hydrogen-bonding inter

297 shown that the nanocage poorly organizes the interfacial water, which in turn creates electric fields

298 acceptor for PCET from Y356 and from Y731 is interfacial water.

299 situ reduction of Ti-LLZTO by Li-metal, the interfacial wettability was improved and a mixed ion-ele

300 des triggers marked dynamical heterogeneity, interfacial wettability, and asymmetric salt-bridging pr