ライフサイエンスコーパス: phase change

1 -14-Cu-i, exhibited a type V isotherm and no phase change.

2 sive characteristics during the liquid-solid phase change.

3 d material can be controlled by a reversible phase change.

4 ntly above 1.0 MJ m(-2), indicating possible phase change.

5 of the leaf signal that mediates vegetative phase change.

6 t interchain arrangement associated with the phase change.

7 or transition accompanying the beta-to-gamma phase change.

8 ators shortly before the commencement of the phase change.

9 pends critically on the amount of cumulative phase change.

10 by imparting local and space-variant abrupt phase change.

11 opmental states and may influence vegetative phase change.

12 longer retention or strong optical pump for phase-change.

13 n to retain detector sensitivity when mobile phase changes.

14 e field of singular optics relying on abrupt phase changes.

15 nscription factors involved in developmental phase changes.

16 e modified arbitrarily by introducing abrupt phase changes.

17 tifying the regulatory control mechanisms of phase change, a detailed understanding of the genetic ar

18 ncover two distinct regimes of the dynamical phase change: a nearly instantaneous crossover into an i

19 through the variance of the motion-corrected phase changes acquired within multiple B-scans at the sa

20 Nucleation initiates phase changes across nature.

21 nded metal-organic frameworks can behave as 'phase-change' adsorbents, with unusual step-shaped CO2 a

22 d enriched to 81 mole % para-xylene, without phase change and at ambient temperature.

23 t to differentiate the effects of vegetative phase change and floral induction on vegetative developm

24 known to have important roles in regulating phase change and flowering.

25 be involved in the regulation of behavioral phase change and gram-negative bacteria-binding proteins

26 ermal energy and fluid flow where needed for phase change and minimizes dissipated energy.

27 g pathway is associated with both vegetative phase change and shifts in epigenetic regulation of a ma

28 on model incorporating the interplay between phase change and spatial movement at the individual leve

29 response time due to the decoupling between phase change and time response through engineered sub-mi

30 for in situ measurements and observations of phase changes and crystal growth processes relevant to a

31 nd the complex atomic mechanisms involved in phase changes and solid state chemical reactions.

32 thawing leads to irreversible changes due to phase changes and water condensation.

33 e-to-adult vegetative transition (vegetative phase change) and the adult-to-reproductive transition (

34 pmental transitions: germination, vegetative phase change, and flowering.

35 c link between calcium transport, vegetative phase change, and inflorescence architecture.

36 miRNAs that influence meristem determinacy, phase change, and leaf polarity.

37 ed with a change in the timing of vegetative phase change, and was primarily attributable to a change

38 ase-changing tones, of control tones without phase changes, and of short tones that consist of a sing

39 se architectures, including their formation, phase changes, and stimuli-response behaviors, is necess

40 ssion of the pi-stacked architecture with no phase change apparent up to 8 GPa.

41 harvesting solar energy for a broad range of phase-change applications.

42 interest for both thermoelectric and optical phase-change applications.

43 le solar energy generation and other related phase-change applications.

44 iscontinuities associated with mineralogical phase changes approximately 410 and 660 kilometers (km)

45 the onset and the progression of vegetative phase change are regulated by different combinations of

46 ing current as a transmitter and a vector of phase changes are measured from the remaining of the coi

47 Phase changes are observed when the wood alloy state cha

48 , such as solid-state chemical reactions and phase changes, are ubiquitous in materials science, and

49 e spacing in both materials, together with a phase change around 200 K in DA2PbI4.

50 e surfaces promotes rapidly reversible redox phase changes as confirmed by calorimetry, X-ray diffrac

51 on of marching locust hopper bands, we study phase change at the collective level, and in a quantitat

52 omic force microscopy can be used to observe phase changes at crystal surfaces where the transformati

53 solution to boost significantly the speed of phase-change-based in-memory logic devices, thus paving

54 Multiple operations in phase-change-based logic devices have been achieved usin

55 while maintaining the superior advantage of phase-change-based logic devices over silicon-based logi

56 tural changes does not coincide with a lipid phase change because little change in fluorescence-detec

57 air stable and show reversible glass-crystal phase-change behavior with a band gap red shift of 0.11

58 PSe(6) (A = K, Rb), which show crystal-glass phase-change behavior, exhibit strong second harmonic ge

59 onding and exhibits reversible crystal-glass phase-change behavior.

60 this is the first account of contact-induced phase changes being studied in an optical trap.

61 e existence of a D" triplication (a putative phase change) beneath the down-welling structure.

62 made of In2 Se3 , which utilizes reversible phase changes between a low-resistance crystalline beta

63 data storage is effected by fast, reversible phase changes between crystalline and amorphous states.

64 65% and resulted in cell cycle (G(1)- and S-phase) changes but only at 21% oxygen.

65 ns had no effect on the timing of vegetative phase change, but ablation of leaf primordia delayed thi

66 the domains reversal occurs with 180 degrees phase change by applying external voltage, demonstrating

67 ittle as 2 s, meaning that thermally induced phase changes can be accurately quantified and additiona

68 wever, for regular phase modulators, a large phase change comes with a slow time response penalty.

69 d switching and may be useful in finding new phase change compositions with superior properties.

70 activation of folate receptor (FR)-targeted phase-change contrast agents (PCCAs) in MDA-MB-231 and M

71 odified MOF exhibits a temperature dependent phase change controlled by steric clashes between interp

72 rter, narrower leaves with leaf polarity and phase change defects.

73 on opens up new possibilities for developing phase-change devices based on atomically thin membranes.

74 athway to the design and characterization of phase-change devices operating in a mixed-mode optical-e

75 Two prototype phase-change devices that might exploit simultaneous opt

76 rphous and crystalline states, of large-area phase-change devices, making it attractive for practicab

77 ractive for practicable pixel fabrication in phase-change display applications.

78 ravascular targets through use of nanoscale, phase-change droplets and photoacoustic imaging, which p

79 The phase-changing electrolyte gel provides a pervading bioc

80 aterials, enabling potential applications in phase-change electronic devices.

81 underlying the acoustic activation of these phase-change emulsions into a bubbly dispersion, termed

82 taneously achieve fast charging rates, large phase-change enthalpy, and high solar-thermal energy con

83 Currently, phase-change films are most commonly deposited by sputte

84 lectrolyte, lithiation of sulfur experiences phase change from a high-order polysulfide to low-order

85 storage roots is a process associated with a phase change from cell division and elongation to radial

86 s maize (Zea mays) plants undergo vegetative phase change from juvenile to adult, they both exhibit h

87 Genetic and epigenetic mechanisms regulating phase change from juvenility to maturity influence direc

88 In the former series, the pH of the aqueous phase changed from basic to acidic during the course of

89 Such a drastic phase change has been theoretically highlighted in the p

90 Several key QTLs related to phase change have been characterized, most of which were

91 because of sintering, carbon deposition and phase changes have proven challenging.

92 ead importance, from underwater operation to phase-change heat transfer applications.

93 through advancement in boiling and quenching phase-change heat transfer processes by nanoscale surfac

94 lied to a wide range of water-harvesting and phase-change heat-transfer applications.

95 fic, protein synthesis-independent induction phase (changes in synaptic weights/temporary tagging of

96 is the first example of a temperature-driven phase change in 3D ZIF frameworks.

97 tric-field-driven, water-mediated reversible phase change in a perovskite-structured nickelate, SmNiO

98 rical pulses on the crystalline-to-amorphous phase change in a single-crystalline Ge(2)Sb(2)Te(5) (GS

99 Vegetative phase change in Arabidopsis is regulated by miR156, a mi

100 central role in the regulation of vegetative phase change in Arabidopsis.

101 e of confocal Raman microscopy in monitoring phase change in biocements; it also demonstrates the pro

102 Vegetative phase change in flowering plants is regulated by a decre

103 We demonstrate that the delay in vegetative phase change in gct and cct is largely due to overexpres

104 these new advances in the molecular basis of phase change in locusts and present some challenges that

105 Phase change in locusts is an ideal model for studying t

106 our understanding of the molecular basis of phase change in locusts.

107 y understood molecular mechanisms underlying phase change in maize, we compared gene expression in tw

108 tron beam irradiation induced local 2H to 1T phase change in MoS2.

109 genes involved in vegetative-to-reproductive phase change in Norway spruce.

110 ion factor in the vegetative-to-reproductive phase change in Norway spruce.

111 the initiation and maintenance of vegetative phase change in plants.

112 t it decays within 20 nm with a considerable phase change in the near-field signal.

113 The vegetative-to-reproductive phase change in tulip (Tulipa gesneriana) is promoted by

114 ing a PCM based on melting-free, low-entropy phase changes in contrast with the GeTe-Sb2 Te3 superlat

115 py to identify polymorphic forms and monitor phase changes in pharmaceutical products for quality con

116 By targeting STAT3-dependent acute-phase changes in the liver, we evaluated the role of liv

117 ive development is one of the most important phase changes in the plant life cycle.

118 However, the multiple reactions and phase changes in the sulfur conversion cathode result in

119 sitions) also provides higher sensitivity to phase changes in weakly scattering samples.

120 In the third phase, changes in abundance of particular proteins, incl

121 if metals associate with NPs in the aqueous phase, changes in bioavailability and toxicology may res

122 e evolution of density-dependent behavioural phase-change in juvenile locusts.

123 on maintaining fiber in order to measure the phase change induced by the electric field of terahertz

124 irnessite-like MnOx (delta-MnO2) undergoes a phase change, induced by comproportionation with cathodi

125 nregulation of these genes during vegetative phase change is associated with an increase in their lev

126 repression; the effect of suo on vegetative phase change is attributable to a reduction in miR156/mi

127 We conclude that vegetative phase change is initiated by a signal(s) produced by lea

128 s and calculations show that this reversible phase change is not observed for a single buffer layer o

129 Most importantly, the phase change is reversible; the beta version of the MOF

130 This phase change is selective for this gold salt, even in th

131 Vegetative phase change is the developmental transition from the ju

132 the juvenile to adult transition (vegetative phase change) is initiated by a decrease in miR156.

133 res separated from a continuous Au film by a phase change material (Ge2Sb2Te5) layer.

134 ulsifiers, nonadecane was chosen as the core phase change material (PCM), and polystyrene, the shell

135 namics simulations of crystallization of the phase change material Ag4In3Sb67Te26 (AIST).

136 ive thermal rectification device that uses a phase change material to achieve a high degree of asymme

137 ing an irreversible transmission change of a phase change material, and capturing terahertz waveforms

138 iscover that MoTe2 is an excellent candidate phase change material.

139 of a local heat application device based on phase change material.

140 nant modes in metallic nanodimers bridged by phase-change material (PCM) sections, material and elect

141 The nebulous term phase-change material (PCM) simply refers to any substan

142 he hollow interiors of gold nanocages with a phase-change material (PCM) such as 1-tetradecanol that

143 ed with dye molecules and then corked with a phase-change material (PCM).

144 The initiator is mixed with a phase-change material and loaded into the cavities of go

145 y requires integration of discrete nanoscale phase-change material features with read/write electroni

146 egrees C, and can be used as a biocompatible phase-change material for NIR-triggered drug release.

147 s of an array of slits which are filled with phase-change material Ge2Sb2Te5 (GST).

148 on irradiation by a near-infrared laser, the phase-change material is melted due to the photothermal

149 Self-assembled nanowire-based phase-change material memory devices offer an attractive

150 Interestingly, K(4)GeP(4)Se(12) is a phase-change material that reversibly converts between g

151 a fishnet metamaterial(MM) based on a metal/phase-change material(PCM)/metal multilayer.

152 -assembled Ge2Sb2Te5 nanowires, an important phase-change material.

153 hylene glycol (PEG) as form-stable composite phase change materials (CPCMs) were prepared to choose t

154 d with the well-developed micro-encapsulated phase change materials (MEPCMs).

155 ions in producing shape-stabilized composite phase change materials (ss-CPCMs) through a facile self-

156 Ge2Sb2Te5 and related phase change materials are highly unusual in that they c

157 o exceed that of the best thermal greases or phase change materials by an order of magnitude.

158 the development of better thermoelectric and phase change materials.

159 cation procedure to create nano-encapsulated phase changing materials (NEPCMs) using a method whose s

160 Phase-change materials (PCMs) are promising candidates f

161 pair-rich, semiconducting materials, such as phase-change materials (PCMs).

162 ries based on metal nanoparticles, nanoscale phase-change materials and molecular switches.

163 Using extremely thin phase-change materials and transparent conductors, we de

164 Phase-change materials are technologically important due

165 ation of photo-switching dopants and organic phase-change materials as a way to introduce an activati

166 Phase-change materials based on Ge-Sb-Te alloys are wide

167 ept demonstration shows how integration with phase-change materials can transform widespread phosphor

168 The technologically most important family of phase-change materials consists of Ge-Sb-Te alloys.

169 ce unit-cells with electronically-controlled phase-change materials embedded inside.

170 Phase-change materials exhibit fast and reversible trans

171 The application of phase-change materials for data storage and memory devic

172 with applications as thermoelectrics and as phase-change materials for data storage, even 22-kHz mag

173 toelectronic framework using low-dimensional phase-change materials has many likely applications, suc

174 The technological success of phase-change materials in the field of data storage and

175 d kinetically constrained crystallization in phase-change materials is provided by investigating stru

176 Phase-change materials offer state-of-the-art thermal st

177 rrently, solar-thermal energy storage within phase-change materials relies on adding high thermal-con

178 o introduce an activation energy barrier for phase-change materials solidification and to conserve th

179 strate that starting from noncentrosymmetric phase-change materials such as APSe(6) (A = K, Rb), we c

180 Phase-change materials switch between two solid states--

181 spontaneous heat loss from thermally charged phase-change materials to cooler surroundings occurs due

182 Phase-change materials undergo rapid and reversible crys

183 New clathrate-based phase-change materials with cage-like structures incorpo

184 nd-store operation by integrating functional phase-change materials with nanophotonic chips.

185 ormed as desired, such as chalcogenide-based phase-change materials, has revolutionized the media and

186 cold (in ice and water); and electricity (in phase-change materials, pumped hydro, hydropower, and hy

187 Phase-change materials, such as meta-stable undercooled

188 ious memory metamaterials were realized with phase-change materials, such as vanadium dioxide or chal

189 bution of optical absorbers dispersed within phase-change materials, to simultaneously achieve fast c

190 Phase-change materials, which can be reversibly switched

191 based on microelectromechanical systems and phase-change materials.

192 the development of better thermoelectric and phase-change materials.

193 cal performances of these chalcogenide based phase-change materials.

194 In cell membranes, a similar phase change may trigger the communication between the m

195 lectronic characterization approach based on phase change measurements at a constant fixed frequency,

196 ecular modeling simulations to elucidate the phase-change mechanism, including the energetic changes

197 tal and theoretical effort to understand the phase-change mechanism, the detailed atomistic changes i

198 Combining metamaterials with phase change media offers a promising approach to achiev

199 alities attained through the exploitation of phase-change media, semiconductors, graphene, carbon nan

200 have emerged, including embedded varactors, phase-change media, the use of liquid crystals, electric

201 eSbTe-based chalcogenide superlattice (CSLs) phase-change memories consist of GeSbTe layer blocks sep

202 y studied in the development of non-volatile phase-change memories.

203 to rock-salt GST) transition used in current phase-change memories.

204 in the development of advanced materials for phase-change memories.

205 eration power, compared with Ge2Sb2Te5-based phase change memory cell at the same size.

206 Here, we demonstrate phase change memory cell based on Ti0.4Sb2Te3 alloy, sho

207 oviding a link between the chemical basis of phase change memory property and origins of giant respon

208 low-power dynamic random access memory-like phase change memory technology.

209 substituting dynamic random access memory by phase change memory.

210 to be operated at high temperatures such as phase change memory.

211 An unconventional phase-change memory (PCM) made of In2 Se3 , which utiliz

212 r manipulating transient-amorphous states of phase-change memory (PCM) materials is reported as a via

213 The operation of resistive and phase-change memory (RRAM and PCM) is controlled by high

214 n junctions could improve the performance of phase-change memory and thermoelectric devices and allow

215 temperature nanoelectronics such as emerging phase-change memory devices which also employ highly dop

216 for efficient thermoelectric converters and phase-change memory devices.

217 resistivity contrast, which is exploited in phase-change memory devices.

218 tion achieved via the melt-quench pathway in phase-change memory involves fundamentally inefficient e

219 Ge-Sb-Te-based phase-change memory is one of the most promising candida

220 g process in chalcogenide superlattice (CSL) phase-change memory materials by describing the motion o

221 lms of pure Ge2Sb2Te5 and N-doped Ge2Sb2Te5N phase-change memory materials can be induced using rapid

222 should open up new ways to develop superior phase-change memory materials, for example, faster nucle

223 mproved energy efficiency and reliability of phase-change memory technologies.

224 Te3 superlattice film adopted in interfacial phase-change memory.

225 nts have been extended to crossbar arrays of phase-change memristive devices.

226 e, bidirectional, all-optical switching in a phase-change metamaterial delivers high-contrast transmi

227 The proposed phase-change metamaterial provides a simple way to reali

228 he optically fast tuning of double FRs using phase change metamaterials(PCMMs) may have potential app

229 non-volatile color-depth modulation in novel phase change nanodisplays allowing for continuous "grays

230 n cell lysate and milk by using solid-liquid phase change nanoparticles as thermal barcodes.

231 repatterned holes can be filled to fabricate phase-change nanostructures from hundreds down to tens o

232 ial melt near 410-km depth and/or additional phase changes near 660-km depth.

233 protected zero reflection yielding to sharp phase changes nearby, which can be employed to radically

234 Here, we present a size-dependent surface phase change occurring in lithium iron phosphate during

235 es display a direct visualization of surface phase changes occurring at the interface at elevated tem

236 activation of UWDM-3, by removing solvent, a phase change occurs.

237 and read and are reversibly switched with a phase change of 180 degrees .

238 structures by utilising the liquid to solid phase change of a composite hydrogel (CH) ink.

239 ear state, which is equivalent to a discrete phase change of pi in the nonlinear polarizability.

240 Laser activation achieved a phase change of the photoresponsive formulations and the

241 ce near-total internal reflection and abrupt phase change of the slit-guided mode.

242 ensors rely on the detection of amplitude or phase changes of light.

243 y- and information-storage processes rely on phase changes of nanomaterials in reactive environments.

244 y believed that ocean circulation drives the phase changes of the AMO by controlling ocean heat conte

245 ilms on the electrodes as well as structural/phase changes of the LCO electrode, as reported in the l

246 re-compensated and can be re-entrained after phase changes of the synchronizing agents.

247 Additionally, nonlinear phase changes of the transmitted terahertz field can be

248 l, it reproduces the experimentally observed phase changes of: 1), pure LPA and DOPA with respect to

249 Here, by leveraging the phase-change of a vanadium dioxide nanolayer, we demonst

250 ting light by imparting local, space-variant phase changes on an incident electromagnetic wave.

251 action pathways for crystalline-to-amorphous phase-change on picosecond timescales remain unknown.

252 s a miRNA controlling floral development and phase change; our results show that miR172 has a higher

253 f freedom are attained by introducing abrupt phase changes over the scale of the wavelength.

254 g of cavitation and provide new insights for phase-change phenomena at the nanoscale.

255 processing unit is embedded into a scalable phase-change photonic network and addressed optically th

256 Phase change plays a prominent role in determining the f

257 nent NLO glass from materials that undergo a phase-change process.

258 Deep insight is gained into the phase-change process; very high densities of connected s

259 d non-fluorescent), graphical, magnetic, and phase change properties of nanoparticles or their differ

260 We report the ready tuneability of phase-change properties in GeSbSe films through composit

261 Operation speed is a key challenge in phase-change random-access memory (PCRAM) technology, es

262 cally addressed non-volatile memory devices (phase-change random-access memory or PCRAM).

263 l DVDs and non-volatile electronic memories (phase-change random-access memory).

264 , through the concatenation of wavelets, the phase changes randomly every few cycles.

265 ffraction analysis (SCXRD), we show that the phase changes result in new narrow-channel forms that ex

266 Paraffin wax was used as a phase-changing sacrificial layer to protect microstructu

267 n plants, miRNAs regulate organ development, phase change, signal transduction and response to differ

268 This half-period Berry phase changes smoothly within one state of the system wh

269 equencies below a few kilohertz we find that phase changes systematically worsen frequency discrimina

270 tions due to its large latent heat, suitable phase change temperature, good thermal reliability, as w

271 Flowering is a major developmental phase change that transforms the fate of the shoot apica

272 The effect of adding salt to the charged phase changes the structure from the primitive cubic ([F

273 Through measurement of the light phase change, the MZI sensor provides an optical platfor

274 These proteins can undergo a physical phase change to form functional granules or other entiti

275 ian response was established by relating the phase change to insertion loss change.

276 n test the frequency discrimination of these phase-changing tones, of control tones without phase cha

277 e room temperature non-volatile proton-gated phase-change transistor is demonstrated based on this pr

278 ed by a plasticizing stimulus that induces a phase change transition of the polymeric membrane from a

279 ric storage capacity; and does not undergo a phase change upon H(2) desorption.

280 ZIF-7 undergoes a displacive, nondestructive phase change upon heating to above approximately 700 deg

281 ple lithium-ion transport pathways and local phase changes upon lithiation in silver hollandite are r

282 -bis(4-pyridyl)propane), undergo spontaneous phase changes upon solvent loss at room temperature.

283 ferenced luminescent sensor for solid-liquid phase change, viscosity, and temperature, with greenish-

284 with PP TC development reflecting vegetative phase change (VPC) in Arabidopsis.

285 The phase change was demonstrated to be unidirectional, reve

286 The process of this phase-change was followed by in situ variable temperatur

287 urce of the factors that regulate vegetative phase change, we examined the effect of root and leaf ab

288 fluid flow conditions, tissue thickness, and phase change were made.

289 Near-ambient phase changes were observed for 1.44 and 1.52 nm nanotub

290 te undergoes rapid recrystallization without phase change when exposed to aqueous Fe(II).

291 the idea of nucleation and growth during the phase change, which had its echo when I later tackled th

292 (LC) spatial light modulator offers a large phase change while keeping fast response time due to the

293 ntually induces the crystalline-to-amorphous phase change with a sharp interface spanning the entire

294 he developmental clock regulating vegetative phase change with leaf morphology.

295 ce contact, tissue thickness, blood flow and phase change with mm to sub mm accuracy are needed.

296 lating the refractive index to exploit rapid phase changes with the drawback of also modulating ampli

297 d other measured properties suggest that the phase change, with composition, may be absent.

298 ble phase separation and its adaptation to a phase change, with up-regulation in each phase of the fi

299 erature-dependent measurements reveal subtle phase changes within the insulating state.

300 or light manipulation and control, the sharp phase changes would be useful in enhancing the beam shif