ライフサイエンスコーパス: melting

1 phere decreased EAIS susceptibility to ocean melting.

2 r phonons are a lot less sensitive to stripe melting.

3 to need an additional cofactor for promoter melting.

4 the context of increased particle loads and melting.

5 tween the mobilities for crystallization and melting.

6 edo combined with enhanced post-depositional melting.

7 ergetic collisions that lead to global-scale melting.

8 owing warm water layer and the rate of basal melting.

9 portance of heat-capacity changes during DNA melting.

10 examples of glasses that exhibit first-order melting.

11 f the transcription bubble to drive promoter melting.

12 e temperature variations affecting degree of melting.

13 h H(2)O is assumed to be incompatible during melting.

14 d the process was described as thermodynamic melting(1), implying that HDA is a glassy state of water

15 conduction and thermodynamic signatures for melting(16), but did not confirm the microscopic structu

16 Increased surface melting(17) could trigger hydrofracturing if it leads to

17 fic presenting a single dissociation peak (T(melting) = 88.7 degrees C).

18 In addition, we find that submarine iceberg melting accounts for over 95% of heat used for ice melt

19 Atmospheric warming is increasing surface melting across the Antarctic Peninsula, with unknown imp

20 te by novel combination of the electron beam melting additive manufacture and hot isostatic pressing

21 sourced primarily from ice shelf and iceberg melting along the eastern Antarctic Peninsula - remained

22 t correlating inversely with their degree of melting, although H(2)O is assumed to be incompatible du

23 ral decomposition, nanoparticle lubrication, melting among others) that are typically thermal in orig

24 n a molecular assay based on High Resolution Melting Analysis (HRMA) as a fast, cost-effective altern

25 on real-time PCR coupled to high resolution melting analysis targeting the COI gene was developed to

26 f allele-specific, asymmetric rapid PCR, and melting analysis.

27 llization to derivatives exhibiting coherent melting and a liquid phase that is stable over a large t

28 l cycling commonly employed for nucleic acid melting and annealing, this is achieved by raising and l

29 riable, three-dimensional geometry linked to melting and calving patterns.

30 tion performance of nanothermites by rapidly melting and coalescing aggregated metal nanoparticles, w

31 l phenomena that range from crystallization, melting and evaporation to the formation of clouds and t

32 identify the transition between initial DNA melting and extensive unwinding as the first initiation

33 s to a post-shock decompression that induced melting and extensive vesiculation in the tektite melt.

34 he Antarctic Ice Sheet by increasing surface melting and facilitating 'hydrofracturing'(1-7), where m

35 al strength of a nonwoven mat of nanofibers, melting and fusion of the nanofibers can be employed to

36 tural and compositional requirements for MOF melting and glass formation are poorly understood.

37 postulate compositional requirements for ZIF melting and glass formation, which may guide the search

38 enhanced by lower degrees of sub-arc mantle melting and higher extents of intracrustal differentiati

39 ciers and ice sheets are driven by submarine melting and iceberg calving from tidewater glacier margi

40 Across the Arctic, glaciers are melting and permafrost is thawing at unprecedented rates

41 ly because of inputs from the ice/snow layer melting and river runoff.

42 ects the volatile partitioning during mantle melting and subsequent volatile speciation near the surf

43 yroxene was not exhausted at high degrees of melting and was retained in the residuum.

44 ecause of strand separation (tension-induced melting) and spontaneous adoption of a conformation term

45 elt), Antarctic ice shelves (increased ocean melting), and Greenland and Antarctic outlet glaciers (d

46 infectious keratitis, 3 (2.48%) for corneal melting, and 1 (0.83%) for corneal perforation.

47 is sensitive to phase transitions, including melting, and allows gathering insights on compositional

48 the Canadian High Arctic during ice-covered, melting, and ice-free conditions.

49 Using stopped-flow techniques and FRET-melting/annealing assays, we confirmed that the rates of

50 single-crystalline fusion zone after e-beam melting are unacceptable (e.g., prone to cracking), or,

51 e domains, which contribute little to mantle melting, are under-represented in compilations of mantle

52 ating interstrand base stacking, rather than melting as generally thought.

53 lifetimes) in DNA bonds at room temperature (melting at 44 degrees C) and thus open up pathways to ne

54 magmas) result from a high degree of mantle melting at high pressures(2) and thus are excellent prob

55 he meteoritic record that document incipient melting at the onset of planetary differentiation.

56 f single Au nanoparticles show heterogeneous melting at the surface followed by density fluctuation d

57 The melting behavior and polymorphism were investigated for

58 functional theory, that similar evidence for melting behavior in zeolitic imidazolate frameworks (ZIF

59 Here, we report the freezing and melting behavior of water (D(2)O) nanoconfined in archit

60 We reproduce both the re-entrant melting behaviour and the polymorphism of the solid phas

61 ed in minerals affect density, viscosity and melting behaviour of the Earth's mantle and play an impo

62 Although the changes in melting behaviour on the nanoscale have long attracted t

63 s may indicate increasing degrees of partial melting beneath D.

64 As the very vibrations invoked in ZIF melting but heretofore unobserved for carboxylate MOFs,

65 of a lattice (similarly one can create local melting by creating divacancies).

66 b1 stabilizes base unpairing regions against melting by molecular machines.

67 rget site DNA base unstacking, flipping, and melting by RAG1 methionine 848 explain how this residue

68 regulated step of transcription is promoter melting by RNA polymerase (RNAP) to form the open promot

69 erase chain reaction (qPCR) instruments with melting capabilities.

70 egrate, as a result of surface and sub-shelf melting caused by global warming.

71 between the mixture components) and the same melting characteristics as the ice cream samples made wi

72 Here, optical melting, circular dichroism, and osmometry data were col

73 esent the same spectroscopic signatures upon melting, common to those observed for other pure late 3d

74 occur under high-power, low-scan speed laser melting conditions.

75 otochemistry versus 48 to 65% to ice surface melting, contributing an additional ~1.86 cm water equiv

76 ds hysteresis, indicative of tension-induced melting; conversely, cyclic stretching of DAP-DNA showed

77 Here we find that submarine iceberg melting cools and freshens the fjord by up to ~5 degrees

78 The presented melting criterion seems to be general for late 3d metals

79 lipid (glycerol monostearate) influences the melting, crystallisation and enthalpy of NLCs and their

80 ltiplexing, referred to as amplification and melting curve analysis (AMCA), which leverages the kinet

81 plexity of the assay and enabling the use of melting curve analysis for validation.

82 f more than 1 product can be recognized when melting curve analysis is performed after the qPCR.

83 Using gel electrophoresis and DNA melting curve analysis, we showed that LiCl-isopropanol

84 3 +/- 0.13%, an increase of 10.0% over using melting curve analysis.

85 of artifact bias from qPCR results using DNA melting curve analysis.

86 Here, we investigated the melting curve and the eutectic composition of four geoph

87 The melting curve of properly folded rRhi o 2 showed partial

88 ides an explanation for the observed CaCO(3) melting curve overturn at about 6 GPa.

89 In olive samples, the derived melting curve was specific presenting a single dissociat

90 he need of fluorescent probes, agarose gels, melting curves or sequencing analysis.

91 ent, in which the speckle method was used as melting detection technique.

92 g Miscanthus in an energy application is the melting during the combustion due to its high alkali sil

93 ic plateau produced by massive decompression melting during the initiation stage of the Hawaiian hot

94 to crack-free 3D printing via electron beam melting (EBM) with preheat as well as selective laser me

95 esis, fluorescence resonance energy transfer-melting, electrospray ionization mass spectrometry, dial

96 thermal annealing at temperatures within the melting endotherm of films.

97 the importance of diffusion coefficients and melting enthalpies in controlling the growth rates, and

98 reflected by a higher thermal stability and melting enthalpy changes of the starches.

99 lian cell and observe multiple annealing and melting events on the same molecules.

100 Thermal melting experiments reveal that DAP substitution raises

101 hysical studies involving circular dichroism melting experiments, microscale thermophoresis measureme

102 ameters are derived from a series of optical melting experiments; however, acquiring enough melt data

103 bunit by computation, circular dichroism, UV melting, fluorescent probes, nuclease accessibility, ele

104 Laser surface melting followed by rapid solidification is an effective

105 similar geochemical behaviour during mantle melting (for example, cerium) was recently found in melt

106 ale confinement leads to the decrease in the melting/freezing point temperature, density, and surface

107 and Zr(0.5)U(0.5)B(12), were prepared by arc melting from pure elements.

108 ikely to involve a transient increase due to melting glaciers.

109 highly incompatible component, suggests post-melting H(2)O enrichment.

110 Two methods - high-resolution melting (HRM) and rhAmp(R) SNP genotyping - were develop

111 ted hardnesses with alloys fabricated by arc-melting, identifying alloys having very high measured ha

112 to the local coordination environment during melting impact the entropy and enthalpy of metal-organic

113 e for microscopic studies of the dynamics of melting in colloidal model systems.

114 bservation, at atomic resolution, of surface melting in individual size-selected Au clusters (2-5 nm

115 an ocean model to simulate submarine iceberg melting in Sermilik Fjord, east Greenland.

116 This transition from carbonate slab melting in the transition zone to slab dehydration in th

117 Ultrafast melting, interaction with silicon-oxide surface layer, a

118 stic of the parent crystals transformed upon melting into a single tetrahedral site with a broad dist

119 Melting is found at 230 K by the sharp split of configur

120 now scavenges air pollutants, and after snow melting, it can induce an unquantified and poorly unders

121 -7 years, based on the extent of heating and melting its host rocks.

122 enables direct characterization of annealing/melting kinetics of nucleic acids without the need for s

123 In this work, the melting line of platinum has been characterized both exp

124 ed results agree and considerably extend the melting line previously obtained in large-volume devices

125 tood solid polymorphism(1,3-5), an anomalous melting line(6) and the possible transition to a superco

126 no first-order transition observed above the melting line.

127 low (corn and olive oil) or high temperature melting lipids (cocoa butter and hydrogenated coconut oi

128 However, a recently developed melting method enables fabrication of large bulk glass s

129 ents requiring keratoplasty owing to corneal melting might benefit from the strengthening effect of p

130 dapt a Methylation-sensitive High-Resolution Melting (MS-HRM) approach from dried blood spot (DBS) sa

131 ) The roasted briquettes were infiltrated in melting NaNO(3) to prepare NaNO(3)/C-PCMs by a infiltrat

132 o ice shelf cavities, causing high ice shelf melting near the ice sheet grounding lines, accelerating

133 structures show that late steps of promoter melting occur within the RNAP cleft, delineate key roles

134 suggests a possible route to creating local melting of a lattice (similarly one can create local mel

135 ple preparation has a profound effect on the melting of a pure substance, and this could be criticall

136 are consistent with very-low-degree partial melting of a Vigarano-type carbonaceous chondrite (CV) f

137 gia Rift is caused by syn-rift decompression melting of a warm, enriched mantle.

138 aid sequence recognition by promoting local melting of already formed DNA heteroduplex and transient

139 The melting of any pure crystalline material at constant pre

140 The melting of cave ice under current climate conditions is

141 in the lake is very low and is sourced from melting of glacial ice and direct release of occluded CO

142 le by optically monitoring the annealing and melting of mirror-image L-DNA surrogates of the PCR prim

143 es can be deposited layer-by-layer via laser melting of nanocomposite powders, which enhance the lase

144 e noritic diogenite was derived from partial melting of pre-existing rocks and had crystallized in th

145 These factors drive the melting of promoter DNA, but how they support RNA primin

146 Melting of the bent crystal starts at the kink and often

147 (MIS) 101 (~2.55 Ma) also signal substantial melting of the EAIS, and peak sea levels during MIS G7 (

148 separate out-of-Beringia dispersal after the melting of the glaciers at the end of the Pleistocene.

149 Enhanced basal melting of the ice shelves is thought to be the ultimate

150 Linoleate promotes melting of the interior slab, which contains ceramide (C

151 e quantum critical point associated with the melting of the spin-glass phase by charge fluctuations d

152 We study the kinetics of crystal growth and melting of two types of colloidal crystals: body-centere

153 ctor of 16 is shown to facilitate the rapid "melting" of opal films even in the absence of "visible"

154 nto the Weddell Gyre, potentially increasing melting on the undersides of ice shelves.

155 ht inhibit degrading processes in idiopathic melting or in ocular inflammatory diseases of the sclera

156 ive origin DNA unwinding but not initial DNA melting or recruitment of helicase-activation proteins (

157 mptions of this correction model are: 1) the melting peak of the correct product can be identified, 2

158 citric acid had two polymorphs identified by melting peaks at 129.97 degrees C and 145.04 degrees C a

159 (DSC) analysis revealed glass-transition and melting peaks of OSA-starch and a cold-crystallization p

160 cts are similar, 3) the relative size of the melting peaks reflects the relative concentrations of th

161 The first order chain-melting phase transition of lipid membranes is observed

162 regular battery configuration due to its low melting point (180.5 degrees C) and high reactivity, whi

163 g skin gelatin showed a significantly higher melting point (42.7 degrees C) compared to tuna and chic

164 late like scales consisting of layers of low melting point alloy (LMPA) phase change materials fully

165 the degree to which particle size lowers the melting point and is found to vary between 300 and 1800

166 but observed alloying processes shift the LM melting point and lead to undesirable formation of addit

167 nce as well as physical properties including melting point and physical state at room temperature.

168 of two natural fatty acids (with a eutectic melting point at 39 degrees C) in a biocompatible, silic

169 The outermost metal layers form a low melting point Bi(33.7)In(66.3) solder shell (72 degrees

170 ical additives are characterized to identify melting point depressants capable of rapidly denaturing

171 Melting point depression increases with decreasing parti

172 This work reviews existing data on the melting point depression to constrain a simple parameter

173 ing is postulated as the root cause of their melting point depressions and physicochemical properties

174 quid state under ambient conditions and have melting point higher than the freezing point of water, r

175 The ice melting point in larvae was -32.5 degrees C as determine

176 ould be critically important where the exact melting point is used as a means for polymorph identific

177 MPA and one with two enclosures of different melting point LMPAs.

178 acteristics (contact angle < 90 degrees ), a melting point of 58 degrees C and a maximum degradation

179 in a small yet significant decrease in their melting point of about 0.3-0.4 K.

180 models predict both the correct experimental melting point of ice and the temperature of maximum dens

181 tem, which provides a route to transform the melting point of interconnects for applications in solde

182 Here, we show how the melting point of the prototypical ZIF-4/ZIF-62(M) framew

183 hesion when operated below the corresponding melting point of the solidified PSLs, engendering ice an

184 The melting point of this ZIF system is a direct function of

185 s C to only 370 degrees C, by far the lowest melting point reported for a three-dimensional porous MO

186 The lowermost metal layer is a high melting point solder and acts as a core.

187 he core and the shell yielding a stable high melting point solder with adjustable melting points.

188 solvents need to be mixed with suitable low melting point supporting electrolytes (e.g., ionic liqui

189 emperatures, show evidence of size-dependent melting point suppression.

190 Additionally, the melting point transitions and the resulting heat of fusi

191 own illustration is the zigzag plot of their melting point versus chain length.

192 approach for chemical depth profiling of low-melting point, high surface roughness SnAg solder bump f

193 f the associated phase change in addition to melting-point depression in deformed or damaged crystals

194 chloroplast phospholipid, contains >40% high-melting-point molecular species (HMP-PG; molecules that

195 Theoretical results for surface and core melting points are in good agreement with experiment.

196 characterized by significant depressions in melting points compared to those of the neat constituent

197 nables the realization of interconnects with melting points in the range of 112 degrees C to 206 degr

198 The melting points obtained with the two techniques are in g

199 th experiments and reliable estimates of the melting points of light and heavy water.

200 be overcome by employing materials with high melting points such as chromium (Cr) and tungsten (W).

201 s by straddling the temperatures across LMPA melting points thereby drastically altering stiffness.

202 le high melting point solder with adjustable melting points.

203 bump with tailored transformation imprinted melting points.

204 the trend in deracemization correlates with melting points.

205 Plateau; release of carbon and mercury from melting polar ice and thawing permafrost; new funding sc

206 s less-differentiated stereotypes, as in the melting pot metaphor.

207 beer strains are the product of a historical melting pot of fermentation technology.

208 The post-electron-beam-melting, pre-solutionizing recovery via sub-solvus annea

209 porative losses experienced during the laser melting process resulted in clad layers with lower chrom

210 in temperatures higher than the acid without melting, producing the respective carbonates and oxides

211 ime amplification data and the thermodynamic melting profile using an affordable intercalating dye (E

212 trade based on their unique high-resolution melting profiles from COI, cytochrome b, and 16S ribosom

213 fat content (SFC) curves and crystallization/melting profiles were determined.

214 zation and ultrasonic treatment narrowed the melting range.

215 The blends expanded fats' melting ranges and enriched their fatty acid composition

216 Glaciers are melting rapidly.

217 near absorption processes, causing localized melting rather than ablation.

218 ed by hydrous flux melting which changed the melting reactions such that clinopyroxene was not exhaus

219 nt diffusion of hydrogen occurring above the melting region, where water-rich melt flows faster than

220 Submarine iceberg melting releases large volumes of freshwater within Gree

221 udy, the fundamental mechanisms behind solid melting remain elusive at the nanoscale.

222 thelial defects, with progression to corneal melting requiring keratoplasty.

223 the restriction-induced double-stranded DNA melting resets the systems.

224 Much of the melting, resolidification, and subsequent cooling take p

225 with an abruptly decreasing degree of mantle melting resulting from the enhanced cooling of the mantl

226 udies have demonstrated that ice shelf basal melting, resulting from the inflow of warm water onto th

227 sses can only indirectly contribute to AA by melting sea-ice.

228 mal stability assay to examine proteome-wide melting shifts after treatment with DMSO, 1 or 20 uM sta

229 EBM) with preheat as well as selective laser melting (SLM) with limited preheat.

230 or of those experiments reporting the higher melting slope.

231 her retention of the long-chain compounds in melting snow and ice.

232 l cyclones, atmospheric lows or troughs, and melting snow.

233 plete tunability in the form of low- or high-melting solids, stand-alone melt-castable explosives, me

234 Hairpin polyamides induce a higher melting stabilization of a DNA duplex containing the unn

235 menable because the promoter recognition and melting steps are much less complicated than in eukaryot

236 h the likely sensitivity to future ice sheet melting, suggests that their export in glacial runoff is

237 l it sublimated without decomposition before melting (T < 134 degrees C).

238 t an unusual confluence of exceptionally low melting temperature (175 degrees C) and inhibited crysta

239 We determined its melting temperature (68.2 +/- 0.6 degrees C) and thermos

240 ght about a significant increase in apparent melting temperature (DeltaT(m) >= +3 degrees C).

241 me digital LAMP (dLAMP) with high-resolution melting temperature (HRM) analysis and use this single-m

242 region (RRDR) of the rpoB gene by the use of melting temperature (T(m) ) information from 4 rpoB prob

243 is results in a tunable wavelength-dependent melting temperature (T(m) ) window (4.5-15 degrees C) an

244 ting in an 490 bp amplicon with a consistent melting temperature (T(m) = 87.8 degrees C).

245 he protein stability of EftM is tuned with a melting temperature (T(m)) around 37 degrees C such that

246 MSP amplicon, and measures the difference in melting temperature (T(m)) between the two probes (Delta

247 ulfonamide modification caused a decrease in melting temperature (T(m)) of both hybrids, it was lower

248 Just below the melting temperature (T(m)) the profiles showed a sharp i

249 20 carbons providing the maximal increase in melting temperature (~20 degrees C) while completely abo

250 the duplex part possess the highest value of melting temperature and a 2-fold higher anticoagulant ef

251 croscopy, sugars content by HPLC and sucrose melting temperature and enthalpy by DSC.

252 Cl) crystals, a well-studied sample with low melting temperature and quantum super-shells of clusters

253 Changes in melting temperature and transitional pH depended on both

254 rolactone), affording independent control of melting temperature and Young's modulus by concurrently

255 experiments in which pressurized ice at its melting temperature is slid over a water-saturated till

256 lipid bilayers composed of a high and a low melting temperature lipid and cholesterol represent a mo

257 We find that crowders can increase the melting temperature of both an 8-mer DNA duplex and a ha

258 Tpm3.1 dimers, show that ATM-3507 shifts the melting temperature of the C-terminus and the overlap ju

259 the more stable, while being lower than the melting temperature of the original orange, or final yel

260 conductivity, (2) greatly increases the ice melting temperature(7-13) to several thousand kelvin, an

261 rmal stability (up to 29 degrees C increased melting temperature) when compared to that of the linear

262 The complete melting temperature, crystallization onset temperature a

263 ty of PCR primers is further evaluated using melting temperature, primer dimer, hairpin structure and

264 ed significant changes on beta-lactoglobulin melting temperature, unfolded conformation and subsequen

265 We attribute a major role to post-melting temperature-dependent diffusion of hydrogen occu

266 r, as indicated by a 9 degrees C increase in melting temperature.

267 emarkable suppression of crystallization and melting temperatures (down to -80 degrees C from 15 degr

268 The cluster core melting temperatures are significantly greater than pred

269 thalate (PET) which has glass transition and melting temperatures of 76 and 250 degrees C, respective

270 due to easily discernable differences in the melting temperatures of the two species along this mini

271 eriments reveal that DAP substitution raises melting temperatures without diminishing sequence-depend

272 The cluster surface melting temperatures, show evidence of size-dependent me

273 Tropomyosins displayed different melting temperatures, which did not correlate with amino

274 states of yeast mtRNAP that explain promoter melting, template alignment, DNA scrunching, abortive sy

275 clad thickness of 65.8 um was achieved after melting ten 50 um thick powder layers.

276 jecta material sustained a greater degree of melting than that likely derived from reactor Unit 3.

277 ggests a previously unobserved transient DNA melting that may occur during double-stranded DNA survei

278 basaltic magmas are the dominant products of melting the mantles of rocky planets is unclear.

279 How much melting the ocean causes depends on the temperature of t

280 ted in a solid matrix are released only upon melting the PCM to trigger a solid-to-liquid phase trans

281 ES23Li, PES23Na, and PES23Cs transform, upon melting the PE blocks, into the Ia3d gyroid morphology.

282 rains under cooled conditions where, upon Ga melting, they became ultra soft, flexible, and stretchab

283 at relies on a controlled failure mechanism (melting) to protect a circuit from overcurrent.

284 d creep resistance at temperatures below its melting transition (T(m)).

285 ogical combination for the prediction of the melting transition and amorphous-solid behavior of the N

286 The lack of a melting transition indicates that these polymers are amo

287 y to monitor the effect of gramicidin on the melting transition temperatures of the two bilayer leafl

288 x 10(5) g mol(-1) and display no observable melting transition, only relatively low glass transition

289 gate along lipid interfaces and traverse the melting transition, share many similar properties with a

290 networks can undergo tunable, high-enthalpy melting transitions over a wide temperature range.

291 erest in unveiling the puzzling processes of melting transitions.

292 s are inconsistent with fractional anhydrous melting typically associated with a mid-ocean ridge sett

293 of Ti-6Al-4V manufactured by selective laser melting using a Renishaw AM 250.

294 and the softening temperature preceding the melting was also lower on the convex (outer) side of the

295 c outlet glaciers (dynamic response to ocean melting) was partially compensated by mass gains over ic

296 e samples are best explained by hydrous flux melting which changed the melting reactions such that cl

297 om these ice shelves is through ocean-driven melting which is controlled by largely unobserved oceani

298 electronic excitation to the thermal lattice melting, which is further verified by molecular dynamics

299 vidence to the understanding of irreversible melting with an unprecedented spatiotemporal resolution.

300 blooming or reduced floral display in early melting years.