ライフサイエンスコーパス: high temperature

1 rostatic interaction in hydrophobic media at high temperature.

2 eas frequented with hot and dry weather, and high temperature.

3 s more pronounced when low DO coincided with high temperature.

4 ith the release of a great deal of energy at high temperature.

5 of SLG1 enhances the tolerance of plants to high temperature.

6 developmental variation during adaptation to high temperature.

7 both land plants and streptophyte algae from high temperature.

8 erance to the photosynthetic apparatus under high temperature.

9 ratures while diffuson-like phonons dominate high temperatures.

10 imaginary (unstable) phonon modes at low and high temperatures.

11 wing high-density gallium oxide nanowires at high temperatures.

12 ed by the technical challenges of imaging at high temperatures.

13 ht the importance of in situ measurements at high temperatures.

14 nced sampling, with unfolding simulations at high temperatures.

15 ion shifts invariant among populations under high temperatures.

16 potential energies of the ITO thin films at high temperatures.

17 racking polymerization processes at room and high temperatures.

18 sette evapotranspiration and leaf cooling at high temperatures.

19 plicability due to poor thermal stability at high temperatures.

20 es whereas weak T-dependence (glass-like) at high temperatures.

21 subjected to quasi-equilibrium conditions at high temperatures.

22 xceptional transport properties only at very high temperatures.

23 by precipitation and negatively impacted by high temperatures.

24 oxic stress caused by protein aggregation at high temperatures.

25 h the low-shore-lengthened response times at high temperatures.

26 hanisms that may affect quinoa seed yield at high temperatures.

27 rom overoxidation and carbon accumulation at high temperatures.

28 design of miniaturized devices operating at high temperatures.

29 ved by heating and oxidizing pure gallium at high temperatures (~ 1000 degrees C) in the presence of

30 pproach to study phase transformation during high-temperature (1050 degrees C) treatment.

31 he compounds from a baking paper to Tenax at high temperatures (150 and 250 degrees C) evidenced an i

32 usly stabilized at high pressure (2 GPa) and high temperature (1600 K), is promising due to its theor

33 e-crystal X-ray diffraction and confirmed by high-temperature (31)P NMR spectroscopy, crystallizes in

34 At high temperature (32 degrees C), material softening play

35 It creeps (deforms plastically with time) at high temperatures (~800 degrees C).

36 odextrin-incorporated OTCs were evaluated at high temperatures (90-120 degrees C) and CO(2) flow rate

37 w geophysical and fluid geochemical data for high-temperature active hydrothermal venting at Dragon H

38 ry and limited in situ studies show that the high-temperature active INPs are associated with bioaero

39 Wheat Kinase START1 (WKS1), is an effective high-temperature adult-plant resistance gene and confers

40 2D film or beads) and high fabrication cost (high temperature, air/moisture-free conditions), thereby

41 The high-temperature, all-inorganic CsPbI(3) perovskite blac

42 The exploration of microstructures in high temperature alloy melts is important for manufactur

43 the exploration of microstructures in other high temperature alloy melts.

44 L12), low temperature (GAPDH and alpha-TUB), high temperature (alpha-TUB and RPS23), all temperatures

45 of 3beta,3'beta-disteryl ether formation at high temperatures, an attempt was made to use the propos

46 rchy is partially conserved during growth at high temperature and alkaline pH, suggesting that heat,

47 arsenic adsorption capacity of kaolinite at high temperature and clarifies its fixation pathway with

48 In combination, high temperature and elevated CO(2) level resulted in lo

49 s and HECNs) are particularly attractive for high temperature and high hardness applications.

50 rience exceptional wellbore conditions, e.g. high temperature and high pressure that adversely affect

51 Consequently, FMP are exposed to high temperature and humidity over long distribution and

52 for sulfur-reducing bioreactors operated at high temperature and low pH was explored.

53 h regime corresponded to the most favorable (high temperature and low salinity) condition for CO(2) u

54 ing the summertime owing to a combination of high temperature and low salinity, while the wintertime

55 HDA9 is stabilized in response to high temperature and mediates histone deacetylation at t

56 les such as hydrogen (H(2)), particularly at high temperature and pressure, are desirable for boostin

57 method-the Haber-Bosch process-that requires high temperature and pressure.

58 an oil-wet rock at subsurface conditions of high temperature and pressure.

59 ally involved in plant tolerance to moderate high temperature and protected root meristematic cells f

60 The alignment is quite stable at high temperature and remains after more than 1000 heatin

61 e carbonyls and creatinine were submitted to high temperature and studied to identify the reactive ca

62 biology, with structural fragility under the high temperatures and acidic environments of therapeutic

63 In plants that were subjected to high temperatures and elevated CO(2) level, glyphosate w

64 thm generates proteins that remain folded at high temperatures and exhibit more pocket diversity than

65 remarkable thermal stability of Z isomers at high temperatures and liquid-phase stability at temperat

66 High temperatures and low humidity are common features o

67 served their activity even after exposure to high temperatures and organic solvents, demonstrating th

68 uced from high purity N(2) and H(2) gases at high temperatures and pressures via the Haber-Bosch proc

69 lity and reduces oxalate content, the use of high temperatures and times is important as it can reduc

70 e able to produce meaningful data at low and high temperatures and when in motion, as it would be if

71 es is reported and their use as long-lasting high-temperature and high-input-power durable solid-stat

72 arose only when susceptible availability was high: temperature and rainfall had net positive and nega

73 Simultaneous low humidity, high temperature, and high wind speeds disturb the water

74 abilizer that is active under high pressure, high temperature, and in saline solutions, greatly enhan

75 he symbionts' photosystem II was impaired at high temperature, and this response was also found acros

76 mates, with no detectable PrD, are active at high temperatures, and lack thermal responsiveness.

77 when operating the systems at low pressures, high temperatures, and low cosolvent fractions in the el

78 onal strength, large oxidation resistance at high temperatures, and optical functionalities.

79 ionts in hospite with giant clams exposed to high temperatures, and such modulation was able to disti

80 ungstate ((NH(4))(2)WS(4)) films by two-step high temperature annealing without additional sulphuriza

81 tal carbide, is being considered for various high temperature applications.

82 ly for circumstances where high salinity and high temperature are involved.

83 Pinning-type magnets with high coercivity at high temperatures are at the core of thriving clean-ener

84 dispersed Rh cations on ceria, prepared by a high-temperature atom-trapping synthesis, are the active

85 beyond conventional solid-state batteries or high-temperature batteries.

86 ssimilate more carbon than C(3) plants under high temperature, bright light, and low CO(2) conditions

87 High temperature brings adverse impacts on the energy ef

88 rmeable heterocyst, which is advantageous at high temperature but deleterious at low temperature for

89 l animals lengthened their response times at high temperatures but animals collected from the low-sho

90 The stripes become dynamic at high temperatures, but LSNO remains insulating presumabl

91 ernal pressure on a sample from conventional high-temperature ceramic synthesis.

92 s into the measuring gas is achieved using a high temperature chromium-silver reactor that retains ca

93 eaction of CaO and O(2) at high pressure and high temperature conditions; ensuing experiments synthes

94 of liquid silicates under high-pressure and high-temperature conditions are critical for modeling th

95 itride (SiTiN) precursor under high-pressure/high-temperature conditions in a large volume high-press

96 endosperm is fully executed under prolonged high-temperature conditions, but at a faster rate.

97 n nothing but H(2) O under high-pressure and high-temperature conditions.

98 ins a formidable challenge, especially under high-temperature conditions.

99 detergent, sodium dodecyl sulfate (SDS), at high temperature, conditions where trypsin is normally i

100 toward high DO levels, especially in uniform high temperature, confirming that Tigriopus can sense en

101 Recently, high-temperature conventional superconductivity in hydro

102 es and power plants due to their outstanding high temperature creep, fatigue and oxidation resistance

103 , bringing forth new grains that degrade the high-temperature creep properties.

104 e, however, typically requires an additional high temperature cross-coupling step following the nanor

105 lewheel' mechanism, is typically observed in high-temperature crystalline polymorphs.

106 s to be subsequently subjected to a long and high temperature curing to enhance their thermoelectic p

107 by eliminating the need of long-duration and high-temperature curing.

108 However, the typical high-temperature deposition of plasmonic TiN using eithe

109 Ga(2)O(3)) as a semiconductor for high power/high temperature devices and deep-UV sensors has grown.

110 king advantage of the large surface area and high-temperature durability of the material, BNNTs utili

111 polished salt, a material that can withstand high temperatures during fabrication and, at the same ti

112 e conclude that sucralose can be degraded at high temperatures, e.g. during cooking or baking of sucr

113 es indicated that sucralose is decomposed at high temperatures, e.g. through cooking.

114 ng is a popular cooking method; however, the high temperatures employ could modify the grilled meat q

115 Despite the high temperatures employed in this key step, no conforma

116 ntal work(6,7) demonstrated that despite the high temperatures encountered in these environments, the

117 ion calls for a shift away from centralized, high-temperature, energy-intensive processes to decentra

118 ns of thermophiles are thermally stable in a high-temperature environment, adopting a strategy of enh

119 achment and entry into host cells.IMPORTANCE High-temperature environments have proven to be an impor

120 In the high-temperature environments needed to perform catalyti

121 ovides new insight into viral replication in high-temperature environments.

122 d with theta-Al(2) O(3) even after prolonged high-temperature exposures.

123 Prolonged high-temperature extreme events in the ocean, marine hea

124 gle-atomic dispersion have to be balanced at high temperature for forming metal-N(x).

125 Ultrathin materials often require high temperatures for growth and processing, which canno

126 is challenging on flexible substrates due to high-temperature growth requirements.

127 ins how both the timing and amplitude of the high-temperature growth response is controlled.

128 ating from the gas-phase reaction during the high-temperature growth.

129 playing low delta(18)O values, which suggest high temperatures (>40 degrees C) in the water column, a

130 omparable to that attainable by conventional high-temperature (>943 K) thermal catalysis.

131 The influence of high-temperature heat treatment on the microstructure, c

132 attractive alternative over the traditional high temperature heterogeneous catalysis.

133 % polycrystals across the high temperature hexagonal (P6(3)/mmc) to low temperatur

134 e, we report the first synthesis of an ultra-high-temperature high-entropy carbide, (TiNbTaZrHf)C, vi

135 end of the experiment because they survived high temperature, high pCO(2) , bacterial exposure, or c

136 al nitrate production from nitrogen involves high-temperature-high-pressure multi-step processes.

137 Subseafloor mixing of high-temperature hot-spring fluids with cold seawater cr

138 tary diamond synthesis methods-high pressure high temperature (HPHT) growth and chemical vapor deposi

139 per site per generation, growth at stressful high temperature (HT; 29 degrees C) is highly mutagenic,

140 plication of single-atom catalysts (SACs) to high-temperature hydrogenation requires materials that t

141 tectonic activity plays an important role in high-temperature hydrothermal circulation at mid-ocean r

142 carbonization of SU-8 derived electrodes at high temperatures in an oxygen-free furnace.

143 he physicochemical stability of sucralose at high temperatures in the context of food processing.

144 related effects (i.e., fire effluents and/or high temperatures) in a modified cone-calorimeter system

145 Alternate scenarios may occur at high temperature, including heat avoidance, where leaves

146 Further, we show that high temperatures increase both epidermal PIF4 transcrip

147 However, the high temperatures induced during lasing can deform the s

148 Our findings reveal that high temperature-induced guard cell movement requires co

149 with their client proteins severely impairs high temperature-induced stomatal opening but has no eff

150 mental evidence that physiologic stress from high temperatures is greater if humidity is higher.

151 us ethylene, carbon dioxide and treatment to high temperatures is not able to reverse the blockage in

152 ed by the reactor were combusted to heat the high-temperature kiln, the electrochemical cement proces

153 vo, this would result in lower ZTL levels at high temperatures leading to longer periods in the Cvi b

154 activity, which restricts its application in high-temperature Li metal batteries for energy storage a

155 s into realizing a stable Li metal anode for high-temperature Li metal batteries with a simple batter

156 it can be facilely operated for rechargeable high-temperature Li metal batteries.

157 crystallization elution fractionation (CEF), high temperature liquid chromatography (HTLC), and therm

158 n alkali metal borates embody a new class of high-temperature liquid-phase materials for carbon dioxi

159 compounds and drugs, certain stresses (e.g., high temperature, low temperature, hypoxia, and radiatio

160 High temperature-low UED combination can be applied to o

161 ciples calculations to uncover the origin of high-temperature magnetism in these superlattices and th

162 Some of the best-performing high-temperature magnets are Sm-Co-based alloys with a m

163 ween weight and temperature, indicating that high temperatures may be a constraint on child nutrition

164 Furthermore, high temperature mechanical testing of the DS alloys sho

165 d to simply as 'genotypes') before and after high temperature-mediated bleaching.

166 ed a reverse-genetics approach to understand high temperature-mediated stomatal opening in Arabidopsi

167 ears ago, coeval with impacts that deposited high-temperature meltglass, melted microspherules, and/o

168 ferent crucial environmental factors such as high temperature, moisture, flexibility and water resist

169 fect can be attributed to the pinning of the high-temperature monoclinic structure, as recently sugge

170 The fraction of the liquid with the high-temperature motif decreased rapidly as the temperat

171 nism: nanoparticles rapidly lose activity by high-temperature nanoparticle decomposition into inactiv

172 tromechanical relay we demonstrate the first high-temperature non-volatile relay operation, with over

173 studied to reduce quality losses due to the high temperatures of conventional processing.

174 Here we show, using metagenomics, a high temperature oil reservoir of marine salinity contai

175 us degradation being observed after 100 h of high temperature operation and 10 redox cycles, suggesti

176 However, high temperatures or toxic solvents are used in some of

177 ntioxidant activity, when exposed to oxygen, high temperature, or light environments.

178 V1 can be activated by low extracellular pH, high temperature, or naturally occurring pungent molecul

179 uding: desiccation, freeze/thaw, exposure to high temperatures, osmotic shock, as well as against enz

180 The high-temperature oxidation resistance of both films is a

181 pathways of the adsorbents upon exposure to high temperature, oxygen, dry CO2, sulfur-containing com

182 we report here characterizes the correlated high-temperature parent phase(11,12) from which various

183 nts on twisted bilayer graphene have shown a high-temperature parent state with massless Dirac fermio

184 t the Gamma point of the energy bands of the high-temperature phase is lifted in the low-temperature

185 high-temperature-pressure laser ablation or high-temperature plasma methods.

186 of magnitude lower than the best commercial high-temperature polymers, and features an unprecedented

187 aluable insight into the growth mechanism in high temperature pressure (HTP) laser ablation where the

188 BSE does not reflect the sole consequence of high temperature-pressure core and mantle equilibration

189 success of large-scale BNNT syntheses using high-temperature-pressure laser ablation or high-tempera

190 However, these materials become unstable at high temperature, preventing improvements in radiative e

191 lity of nanoparticles on the supports during high temperature processing remain enigmatic.

192 tion of Gallium oxide with muscovite enables high-temperature processing as well as excellent flexibi

193 However, the high-temperature processing required for ex-solutions (>

194 High temperature promotes guard cell expansion, which op

195 ials due to their outstanding refractory and high-temperature properties.

196 onstant versus THF concentration even in the high-temperature, rapid-exchange limit affords the solva

197 ation using classical chemical methods (i.e. high temperature, rare metals).

198 ation of radioiodine have generally involved high temperature reactions or strongly oxidizing conditi

199 densation that avoids the transition metals, high temperatures, reagent excess, and air-sensitive rea

200 erstood by attributing it as the first known high temperature realization of a singlet ground state m

201 n = La, Ce, and Pr) framework synthesized by high temperature reduction and demonstrate that later Ln

202 aintain the period of the circadian clock at high temperatures redundantly with UCH1 and UCH2.

203 Females avoided high temperatures regardless of DO levels.

204 The thermal treatment under high temperatures required in the production of granulat

205 ) secretes the chaperone and serine protease high temperature requirement A (HtrA) that cleaves gastr

206 e trophoblast cells positive for cytoplasmic high temperature requirement A1 (Htra1), a marker of cel

207 OXO3a nuclear translocation, and upregulated high temperature requirement A2 (HtrA2) expression to pr

208 the region of the trimeric serine hydrolase high-temperature requirement 1 (HTRA1) are associated wi

209 the existence of an additional intracellular high-temperature response pathway in plants.

210 ld tolerance across a species range, whereas high temperature responses are likely constrained, both

211 ontrasting temperature regimes revealed that high temperatures resulted in coordinated up-regulation

212 sors rapidly and simultaneously pyrolyzed at high temperatures, resulting in nuclei with a small size

213 Long-term experimental evolution under high temperature reversed the short-term stimulation of

214 ular, in Arabidopsis (Arabidopsis thaliana), high temperature reversibly inactivates PHYB, reducing p

215 The thermodynamic stability of Pd under high-temperature rWGS conditions is associated with Pd-T

216 endospores can survive prolonged exposure to high temperatures, sediments were incubated at 80-90 deg

217 pomegranates and ultrafiltration followed by high temperature short-time pasteurization was used to m

218 The high-temperature short-time (HTST, 72 degrees C, 15 s) p

219 In continuous high-temperature short-time treatments, it was shown how

220 How the high-temperature signal is perceived and transmitted to

221 The resultant high-temperature single atoms exhibit a superior thermal

222 The structure, solved using high-temperature single-crystal X-ray diffraction and co

223 these limitations, we developed an ultrafast high-temperature sintering (UHS) process for the fabrica

224 for separating these products efficiently at high temperatures, so that they outperform the state-of-

225 sibility of a wide variety of high-power and high-temperature solid-state lighting, lasing, and displ

226 cryo-EM structures of proteins vitrified at high temperatures, solve 12 structures of an archaeal ke

227 rovides a state-of-the-art test platform for high-temperature soot formation under engine conditions.

228 By contrast, high-temperature specialists of F. thermalis constitutiv

229 depositing peak concentrations of platinum, high-temperature spherules, meltglass, and nanodiamonds,

230 n energy density, electrochemical stability, high temperature stability, and safety.

231 ial to improve the mechanical properties and high-temperature stability over traditional ceramics, an

232 nets are excellent candidates owing to their high-temperature stability.

233 nce to theories that explain the exceptional high temperature strength of similar alloys.

234 tion of the stigma is a frequent response to high temperature stress and, being a cause of reduced fe

235 a key role in the response of rice plants to high-temperature stress at both seedling and reproductiv

236 ate change, breeding crop plants tolerant to high-temperature stress is of immense significance.

237 terminant of grain yield and is sensitive to high-temperature stress.

238 highly sensitive to both HL intensities and high-temperature stress.

239 The lattice dynamics and high-temperature structural transition in SnS and SnSe a

240 al engineered defects in irradiated-annealed high temperature superconducting wires based on epitaxia

241 We present promising results of novel high-temperature superconducting (HTS) shim coil prototy

242 e rise to the pseudogap state from which the high-temperature superconducting state emerges.

243 e-based optoelectronics and exciton-mediated high-temperature superconductivity(13).

244 ic effect(2), the quantum Hall effect(3) and high-temperature superconductivity(4)-and their critical

245 entangled states, a better understanding of high-temperature superconductivity, and quantifying open

246 e a key point in the debate on the origin of high-temperature superconductivity.

247 obtains intrinsic monolayer crystals of the high-temperature superconductor Bi(2)Sr(2)CaCu(2)O(8+del

248 Here we report a high-temperature superconductor coil that generates a ma

249 The charge density wave in the high-temperature superconductor YBa(2)Cu(3)O(7-x) (YBCO)

250 While such states have been reported in high-temperature superconductors and dilute magnetic sem

251 the extraordinary properties of the cuprate high-temperature superconductors arise from doping a str

252 Charge density waves (CDWs) in the cuprate high-temperature superconductors have evoked much intere

253 electronic properties of cuprates and other high-temperature superconductors remains controversial d

254 close resemblance to similar observations in high-temperature superconductors(15-21) provides new evi

255 relevant to strongly correlated electrons in high-temperature superconductors(9).

256 thought to capture the essential physics of high-temperature superconductors, magnetic insulators an

257 s and fermions in a lattice, gauge theories, high-temperature superconductors, quantum spin liquids,

258 waves (CDWs) in most members of the cuprate high-temperature superconductors, the interplay between

259 > ~ 0.3 near T(c) that is a common value for high-temperature superconductors.

260 Cooper-Schrieffer theory or even observed in high-temperature superconductors.

261 attain the atomic metallic hydrogen state or high-temperature superconductors.

262 ll nanoparticles on carbon supports by rapid high temperature synthesis method offers new opportuniti

263 s provide mechanistic understanding of rapid high temperature synthesis of metal nanoparticles on car

264 been realized because of the limitation of a high-temperature synthetic route and the limited underst

265 and exhibit an abrupt change in behavior at high temperatures T/T(c) >~ 0.5.

266 ain evidently drew inspiration from adjacent high-temperature technologies.

267 hange because molluscs are better adapted to high temperatures than other taxa, as demonstrated by th

268 At high temperature, the decomposition of 3R-MoN(2) leads t

269 articular, after annealing at a sufficiently high temperature, the real part of the permittivity show

270 of isoprenoid biosynthesis repressed P(n) at high temperatures through a mechanism that was independe

271 accessible under solvothermal conditions at high temperature, thus opening the door for the isolatio

272 When annealed at high temperature to eliminate oxygen vacancies, Al is do

273 erproduce glycolipid isomers associated with high temperature to levels unattained by plastic strains

274 nt processes typically require substantially high temperature to overcome the activation barriers for

275 The synthesis of complex oxides requires high temperatures to overcome barriers imparted by solid

276 fferentiation of SLG1 confers indica rice to high-temperature tolerance, and tRNA thiolation pathway

277 se findings do not remove the requirement of high temperature toward bulk silica electrochemical redu

278 essary to reliably model the XRD patterns of high-temperature transition alumina.

279 stacking formalism for the quantification of high-temperature transition aluminas.

280 High-temperature treatment of gamma-Al(2) O(3) can lead

281 led carbonization and nitrogen doping during high-temperature treatment.

282 High temperature treatments were associated with increas

283 gradation and loss of morphology in NTs upon high-temperature treatments (>600 degrees C) in a reduci

284 However, a high-temperature two-qubit logic gate has not yet been d

285 plasma is a challenging task because of the high temperatures typically associated with the plasma s

286 profile of pea protein beverage during Ultra High Temperature (UHT) processing and subsequent refrige

287 The effects of pasteurization and ultra-high temperature (UHT) treatment were comparable for bot

288 the optical properties of ITO thin films at high temperatures up to 800 degrees C using spectroscopi

289 alcogenide structures with good stability at high temperatures (up to 1,373 kelvin) and achieving hig

290 measured at ambient conditions as well as at high temperatures (up to 150 degrees C) and high pressur

291 d, whose actuated shape can be locked-in via high-temperature UV exposure.

292 This insulation shields them from high temperature variability and low surface temperature

293 y under harsh conditions of low rainfall and high temperature variability and never under relatively

294 ly at small concentrations of gallium and at high temperatures, where it becomes extremely sensitive

295 nt layers were exposed to fire effluents and high temperatures, while in the CH test chamber, the sam

296 e effect of current statin use, on days with high temperature, with either daily average temperature

297 se assemblies reveal Curie-Weiss behavior at high temperatures, without pairing of the 5f(2)-electron

298 g thermal stability inspires us to develop a high temperature X-ray detector with stable response at

299 tracked using thermogravimetric analysis and high temperature X-ray diffraction and showed a lower fo

300 lysing and DNA denaturation occurred in the high-temperature zone whereas in situ specific detection