ライフサイエンスコーパス: dissipation

1 and crucial process in driving space energy dissipation.

2 n scheme selecting a basis of modes based on dissipation.

3 icro-structured optical fibres on the energy dissipation.

4 (T(b)) by balancing heat production and heat dissipation.

5 gy of separation and the irreversible energy dissipation.

6 ity, self-recovery, self-healing, and energy dissipation.

7 e of ultraviolet and infrared cutoffs due to dissipation.

8 t shuttles for mediating excess light energy dissipation.

9 res in viscous fluid are subjected to energy dissipation.

10 rials to exhibit reusable solid state energy dissipation.

11 eresis to roughness rather than viscoelastic dissipation.

12 fferent current pathways that optimize power dissipation.

13 onal electron-hole pairs rather than by heat dissipation.

14 paration, commonly explained by viscoelastic dissipation.

15 onance, and quartz crystal microbalance with dissipation.

16 nes the effects of adhesion, elasticity, and dissipation.

17 en the layer number and resistance to charge dissipation.

18 eopontin to hydroxyapatite, enhancing energy dissipation.

19 hlea uses cellular actuators to overcome the dissipation.

20 n centers with minimal losses due to thermal dissipation.

21 iol appears to promote vasodilation and heat dissipation.

22 volume of material involved in impact energy dissipation.

23 ocesses of vibrational relaxation and energy dissipation.

24 It governs transport properties, wear and dissipation.

25 ertz generation and cause additional thermal dissipation.

26 t water mass, only four days before the ME's dissipation.

27 , jet formation, jet collimation, and energy dissipation.

28 ulence is generally accompanied by increased dissipation.

29 ersion(5,6), quantum interference(7,8), heat dissipation(9,10) and electronic noise(11) at atomic and

30 ystem where Landau damping plays the role of dissipation, a collisionless plasma is effectively dissi

31 ased on the adiabatic-connection fluctuation-dissipation (ACFD) theorem (namely the Rutgers-Chalmers

32 ary conserved paracrine regulation of energy dissipation across species.

33 both experimental parameter fluctuations and dissipations along dark states.

34 Least Action; the Principle of Minimum Power Dissipation, also called Minimum Entropy Generation; and

35 Lhcx1/2/3 mediated inducible thermal energy dissipation and a reduction in the functional absorption

36 These approaches unavoidably lead to heat dissipation and a temperature rise, which can modify del

37 rtantly, our theory reveals that the damping dissipation and active reciprocal interaction (driving)

38 As we control dissipation and amplification in a nanophotonic system,

39 ing transitions by engineering time-periodic dissipation and coupling, which are realized through sta

40 and paves the way for exploiting correlated dissipation and decoherence-free subspaces of quantum em

41 y, which in turn drastically increases power dissipation and degrades performance.

42 Our results document the dissipation and dissemination off farm of ARGs under Fin

43 echanical energy budget and show that energy dissipation and freshwater content stabilization by eddi

44 In particular, TBR can dominate heat dissipation and has become increasingly important due to

45 Quartz crystal microbalance with dissipation and isothermal titration calorimetry measure

46 To balance the energy surplus, eddy dissipation and its role in gyre stabilization must have

47 while gaining recoverable hysteretic energy dissipation and maintaining its original extensibility.

48 dvantages of deeper penetration, less energy dissipation and minimal normal-tissue toxicity over trad

49 is reported for simultaneous determination, dissipation and risk assessment of fipronil and its meta

50 The low dissipation and the antenna's subwavelength spatial defi

51 light supports MAAs playing a role in photon dissipation and thermoregulation with a possible role in

52 requirement of zeaxanthin for rapid thermal dissipation and unsaturated fatty acids for membrane flu

53 able to show that gas damping, thermoelastic dissipation, and anchor damping are not significant diss

54 ectroscopy, quartz crystal microbalance with dissipation, and electron microscopy, to understand the

55 local remodeling tunes stress production and dissipation, and how this in turn shapes long range flow

56 lects the strength of the external drive and dissipation, and the transition is described as a loss o

57 e as 0.45%, which is not accompanied by heat dissipation, and, for excitation density of 8 mJ cm(-2),

58 omechanical resonators with ultra-low energy dissipation are essential for a wide range of applicatio

59 nstrate that these intrinsic forms of phonon dissipation are greatly reduced (by >90%) by nonlinear s

60 Here, Joule heating and inefficient thermal dissipation are shown to be major obstacles toward high

61 erministic protocols, lower bounds on energy dissipation arise from the thermodynamic friction associ

62 This energy dissipation arises from the storage and non-equilibrium

63 neration in mitochondria and promotes energy dissipation as heat.

64 according to the Principle of Minimum Power Dissipation as put forth by Onsager.

65 ccelerated vibrational energy relaxation and dissipation at the ice surface for hydrogen-bonded OH gr

66 ce at which energy flux into photoprotective dissipation became greater than ETR was observed.

67 artments in series while circumventing power dissipation before contact.

68 in contrast has a fundamental minimum power dissipation bound.

69 This odd viscosity does not lead to energy dissipation, but gives rise to a flow perpendicular to a

70 aspase activation, or mitochondrial membrane dissipation by DOX, in human cancer cell lines.

71 he photosynthetic antenna complexes activate dissipation by leveraging the sensitivity of the photoph

72 ished isothermal calorimetry to measure heat dissipation by living zebra-fish embryos and to estimate

73 ssibility of efficient multifunctional shock dissipation by MOFs was suggested by static high pressur

74 OFs) have suggested the potential for energy dissipation by multiple mechanisms.

75 different physical mechanisms of local force dissipation by the k-fiber limit force transmission to p

76 mpact resistance is attributed to the energy dissipation by the rotating anisotropic layers.

77 We find that shock wave dissipation by ZIF-8 occurred by multiple processes: pow

78 In AQFP logic, dynamic energy dissipation can be drastically reduced due to the adiaba

79 Photon scattering and other forms of dissipation can be negligibly small, which would seem to

80 Our model suggests that an appropriate dissipation can enhance the tuning quality by reducing t

81 expression dynamics, in which nonequilibrium dissipation can suppress fluctuations.

82 We introduce the parameter of dissipation capacity by which several sizes of liposome

83 The specific energy dissipation capacity of the T-type is slightly greater a

84 state, which may provide a permanent energy dissipation channel.

85 ion of electrical, thermoelectric and energy dissipation characteristics of molecular junctions.

86 nce and up to 27 times greater strain-energy dissipation compared to those printed from a commerciall

87 Using the model, we investigated how dissipation components in the cochlea affect its functio

88 strength, poroviscoelastic responses, energy dissipation, conductivity, and mass diffusivity also nee

89 overned by the vortex-stretching and viscous dissipation contributions, similar to non-reacting flows

90 os (10(4) -10(5) ), and the maximized energy dissipation density, W.

91 the system studied, we find no evidence for dissipation-dependent behaviour, nor for any CC in the s

92 vide opportunities to realize high-speed low-dissipation devices.

93 s a result, particle mass becomes dressed by dissipation due to self-interaction.

94 alytical and numerical analysis of the power dissipation due to the dielectric loss are in good agree

95 ip memory, but they suffer from large energy dissipation due to the large current densities required.

96 ttributable to the increased internal energy dissipation during the detachment process.

97 te in operando effects and origins of energy dissipation during tunneling events, and, ultimately, en

98 DC-induced frequency shifts (Deltaf), dissipation energy (DeltaD), and ratios thereof (Deltaf/

99 Here, we demonstrate a novel dissipation engineering strategy that can support stable

100 ults motivate quantum control techniques for dissipation engineering to boost spin lifetimes in diamo

101 yed in the current work as probes for energy-dissipation enhancement.

102 Moreover, it posits that, to minimize energy dissipation, external control should drive the system al

103 The dielectric dissipation factor of Al(0.52)In(0.48)P was estimated as

104 regard to chemical properties and dielectric dissipation factors.

105 ices controlled by pure spin currents: a low-dissipation flow of electronic spins with no net charge

106 materials exhibit similar solid state energy dissipation for loads applied along the various axes of

107 ased magnetic devices could harvest the heat dissipation for magnetic sensors, thus contributing to t

108 t properties be well understood because heat dissipation frequently limits performance in these devic

109 on, we observe slow, nanosecond-long thermal dissipation from the selectively excited organic mode to

110 g behavior, where the contribution to energy dissipation from viscous flow dominates over the entire

111 light-harvesting and photoprotective energy dissipation functions within pigment-protein complexes.

112 This switching mechanism offers low energy dissipation, good reversibility, and high symmetry in pr

113 address this knowledge gap, we investigated dissipation half-lives (DT50s) of 31 substances (mainly

114 Dissipation half-lives (DT50s) were highly variable betw

115 We studied the dissipation half-lives of 10 micropollutants in sediment

116 oroplast protection: enhanced thermal energy dissipation, higher carotenoid to Chl ratio and de-epoxi

117 he first clear, direct detection of Akhiezer dissipation in a MEMS resonator, which is widely conside

118 Here, we show how to describe dissipation in a scalar field theory.

119 tein-1 (UCP1) plays a central role in energy dissipation in brown adipose tissue (BAT).

120 microfluidic systems with significant energy dissipation in conductive fluids.

121 1 (LHCSR1) protein, which is responsible for dissipation in green algae and moss.

122 The location of energy dissipation in powerful extragalactic jets is currently

123 tion from primarily solid-like, viscoelastic dissipation in the linear regime to primarily fluid-like

124 Expressions derived take full account of dissipation in the metal with non-universal behaviour ex

125 Others neglect viscous dissipation in the organ of Corti but consider fluid vis

126 radation can be mitigated by minimizing heat dissipation in the pump lines.

127 n detail the velocity, vorticity and viscous dissipation in the shear wave field and around the silic

128 solid at the moving contact line, enhancing dissipation in the solid phase.

129 conducted to predict the activity and power dissipation in the target.

130 lasmonic nanostructures, due to rapid energy dissipation in these systems.

131 turn off" mitochondrial function through PMF dissipation in tissues with light.

132 rol the balance between light harvesting and dissipation in vivo.

133 uncoupling protein-1 (Ucp1) regulates energy dissipation in white adipose tissue (WAT) depots.

134 regime involves less deformation, thus less dissipation, in the solid phase.

135 e applied this approach to investigate dsRNA dissipation (including dilution, degradation, and adsorp

136 ductive cleavage divisions, the rate of heat dissipation increases from ~60 nJ . s(-1) at the two-cel

137 rgy deposition and consequent thermal energy dissipation induced by energetic particles, a fundamenta

138 Power dissipation is a fundamental issue for future chip-based

139 Photo-induced non-radiative energy dissipation is a potential pathway to induce structural-

140 Energy dissipation is an unavoidable phenomenon of physical sys

141 Because the viscous dissipation is considered to be detrimental to the funct

142 In living systems, for example, the dissipation is directly related to the hydrolysis of fue

143 Identifying dissipation is essential for understanding the physical

144 and scanning gate microscopy shows that the dissipation is governed by crosstalk between counterprop

145 Understanding quantum dissipation is important from both theoretical perspecti

146 The dissipation is introduced via the electron-phonon coupli

147 s findings-the flux-maximizing allocation of dissipation is not even.

148 ough the AH resistance is not quantized, and dissipation is present, our measurements suggest that th

149 electronic stopping the two avenues in which dissipation is usually treated.

150 The rate of entropy production, or dissipation, is a measure of the statistical irreversibi

151 result, AQFP could overcome the power/energy dissipation limitation in conventional superconductor lo

152 This paper explores dissipation limits in 4H monocrystalline silicon carbide

153 we drive domain walls to this limit in a low-dissipation magnetic insulator using pure spin currents

154 offers the prospect of realizing low energy dissipation magnetic memories.

155 ial growth to device performance and thermal dissipation measurements before and after transfer.

156 Instead of local Joule heating, however, the dissipation mechanism comprises two distinct and spatial

157 ces that are more complex than a simple heat dissipation mechanism dominated by acoustic phonons, whi

158 That is, it does not depend on a particular dissipation mechanism of inter-particles collisions, pro

159 tion, and anchor damping are not significant dissipation mechanisms for these resonators.

160 peratures in granular mixtures for different dissipation mechanisms of inelastic inter-particle colli

161 The results provide insights into heat dissipation mechanisms of Joule heated nanotube devices

162 ormance of MEMS resonators is constrained by dissipation mechanisms, some of which are easily detecte

163 usly crosslinked networks and lack of energy dissipation mechanisms.

164 trochemical quartz crystal microbalance with dissipation monitoring (EQCM-D) with simultaneous in sit

165 g with both Quartz Crystal Microbalance with Dissipation monitoring (QCM-D) and EIS.

166 me-resolved quartz crystal microbalance with dissipation monitoring (QCM-D) and microscopy-based cell

167 Using a quartz crystal microbalance with dissipation monitoring (QCM-D) biosensor functionalized

168 col using a quartz crystal microbalance with dissipation monitoring (QCM-D) to separate and individua

169 metry (NR), quartz crystal microbalance with dissipation monitoring (QCM-D), surface plasmon resonanc

170 ng, using a quartz crystal microbalance with dissipation monitoring (QCM-D), to detect exosomes by ex

171 Using quartz crystal microbalance with dissipation monitoring (QCM-D), we determine the affinit

172 along with quartz crystal microbalance with dissipation monitoring and computer simulations to quant

173 s of exosomes, leveraging both frequency and dissipation monitoring for use in bioanalytical characte

174 roscopy and quartz-crystal microbalance with dissipation monitoring to access the real-time kinetics

175 Dissipation monitoring was also shown to be 8 times more

176 A quartz crystal microbalance with dissipation monitoring was used to identify the mechanis

177 cterized by quartz crystal microbalance with dissipation monitoring, while the residual valency of im

178 tions using quartz crystal microbalance with dissipation monitoring.

179 t, thermodynamic notions of energy, work and dissipation must be established for these open chemical

180 We treat dissipation non-perturbatively, represent it by a biline

181 l organisms are different, leading to energy dissipation occurring at different time scales.

182 e molecular torus, demonstrating that energy dissipation occurs ~1 parsec from the black hole (or ~10

183 nput impedance of 500 Omega with a low power dissipation of 40 muW.

184 We study heat dissipation of a multi-wall carbon nanotube (MWCNT) devi

185 Remarkably, dissipation of a single SF within a monolayer induces cy

186 downstream from the WWTP showed the fastest dissipation of all micropollutants after sediment RNA no

187 which we demonstrate through the rapid heat dissipation of an elastomer-mounted extreme high-power L

188 ogenous sleep fail to influence the onset or dissipation of anesthesia.

189 ipation of eddies, with a strong bias toward dissipation of anticyclonic eddies, is directly linked t

190 the light-harvesting antenna, triggering the dissipation of captured light energy.

191 A major component is thermal dissipation of chlorophyll singlet excited states and is

192 We found that substantial dissipation of eddies, with a strong bias toward dissipa

193 Finally, the dissipation of effects over time for many outcomes highl

194 f AOB, but possibly important as a route for dissipation of electrons at high ammonium concentration.

195 Steady dissipation of energy is a crucial property that disting

196 the non-adiabatic coupling and slow down the dissipation of energy to heat.

197 he connecting silver particle with almost no dissipation of energy.

198 during enzyme turnover, without significant dissipation of energy.

199 ssive capacity for rapidly inducible thermal dissipation of excess absorbed energy (qE), provided by

200 ble, photoactive protein involved in thermal dissipation of excess energy absorbed by the light-harve

201 ture adopted by current batteries limits the dissipation of heat and pressure within the cells.

202 nterplay between atom-light interactions and dissipation of light from the cavity have previously bee

203 rmal energy input, so its presence indicates dissipation of mechanical energy or strong ultraviolet i

204 ws a surprising potential for absorption and dissipation of mechanical shock.

205 We characterize how the production and dissipation of network stress depend, individually, on c

206 hloroplast-mitochondria coupling allows safe dissipation of photosynthetically derived electrons via

207 uction, inhibition of protein synthesis, and dissipation of proton gradients.

208 ether these proteins are involved in thermal dissipation of PSI excitation energy, in addition to the

209 MOFs may prove useful in the dissipation of shock wave energy through large structura

210 pported approach to accurately represent the dissipation of small-scale internal tides and their indu

211 Due to the dissipation of SPIOs from the injection site, quantitati

212 e found that the majority of acoustic energy dissipation of the cochlea occurs within the organ of Co

213 Ohm's Law plots confirm the superior heat dissipation of the HSCE capillary compared to a similarl

214 Instead, sorafenib induces rapid dissipation of the mitochondrial membrane potential (Del

215 o grow to sufficiently large mass before the dissipation of the protoplanetary disk.

216 ra with 13 Hz resolution at room temperature.Dissipation of the sensor is a limiting factor in metrol

217 In nanoscale metrology, dissipation of the sensor limits its performance.

218 the gas-giant cores must have formed before dissipation of the solar nebula, which likely occurred w

219 e outlets that allow for storage or harmless dissipation of their energy.

220 substrate at near ambient temperature, where dissipation of their kinetic energy produces strong adhe

221 The dissipation of this heterogeneity commenced 14.6 kyr ago

222 e the dynamics of congestion propagation and dissipation of traffic in cities using a simple contagio

223 nance of a constant helicity state after the dissipation of twist helicity by viscosity.

224 emonstrate a passive NOT gate with an energy dissipation of ~1 fJ/bit at 640 Gb/s and use it as a bui

225 ly implemented in silicon (Si), their energy dissipation often reaches the quantum limits of Si, whic

226 stigate the effects of both qubit and photon dissipation on the phase transition and on the instabili

227 Here, we identify the dominant energy dissipation pathways in few-layer MoS2 nanoelectromechan

228 Viewing the atomic-scale motion and energy dissipation pathways involved in forming a covalent bond

229 A transition in the dominant dissipation pathways occurs at T 110 K with relatively l

230 This is the first time a study has provided dissipation patterns for thiocyclam and nereistoxin.

231 The dissipation patterns of cyantraniliprole and its metabol

232 ding of the rapidly inducible thermal energy dissipation process and its mechanistic implications in

233 Because the heat dissipation process is proportional to light-driven thyl

234 enhance PRP photodegradation and divert PRP dissipation processes away from the production of 34DCA,

235 echniques is required to understand the heat dissipation processes during the device operation.

236 (NPQ) is a proxy for photoprotective thermal dissipation processes that regulate photosynthetic light

237 We find that dissipation promotes a gap in momentum space and reduces

238 ther insight into the much-overlooked energy-dissipation properties of LCEs and can inspire the devel

239 y (XPS) and Quartz Crystal Microbalance with Dissipation (QCM-D) measurements confirmed the successfu

240 taneous LSPR and quartz crystal microbalance-dissipation (QCM-D) measurements.

241 sometry and quartz-crystal microbalance with dissipation (QCM-D), as well as density-functional theor

242 he use of a quartz crystal microbalance with dissipation (QCM-D).

243 fine structure" constant [Formula: see text] Dissipation quenching occurs when dispersing plasmon mod

244 normalized RMS error of 3.43 x 10(-4) in the dissipation rate for a 60(3) element mesh.

245 gestion propagation rate beta and congestion dissipation rate mu.

246 on up to a critical turbulent kinetic energy dissipation rate of 10(-6) (W kg(-1)), above which the s

247 he detection of shifts in both frequency and dissipation rate of mechanical vibrational modes, in an

248 stable, and unstable phases depending on the dissipation rate.

249 fault that should equal or exceed the energy-dissipation-rate along the slipping fault.

250 udies have linked cell damage to high energy dissipation rates (EDR) and have predicted that for smal

251 ate the effect of increasing salinity on the dissipation rates of antibiotics in tropical flooded soi

252 there was no overall salinity effect on the dissipation rates of antibiotics, suggesting that common

253 ECD 308 standard to account for variation of dissipation rates of micropollutants due to differences

254 ished tidal amplitudes and associated energy dissipation rates, reaching 10-50% of today's rates, dur

255 2 GHz, an order of magnitude larger than the dissipation rates.

256 nd the bubble experiences these large energy dissipation rates.

257 stem is shown to have a large interaction-to-dissipation ratio (cooperativity exceeding 100), reachin

258 omputation of the nonequilibrium fluctuation-dissipation ratio for the 3D Edwards-Anderson Ising spin

259 o dynamic regimes: a regime in which viscous dissipation reduces the actuation speed and a regime gov

260 hat limits corneal motion and reduces energy dissipation, reflected in a lower corneal hysteresis.

261 y of a protein is to violate the fluctuation-dissipation relation through nonergodic sampling of its

262 The mechanisms of dissipation remain debated, largely due to two challenge

263 Furthermore, the minimal power dissipation required to account for enzyme enhanced diff

264 sized particles (ESPs)/mL for frequency and dissipation response, respectively, i.e., clinically rel

265 tum cutoff k (D), which realizes a synthetic dissipation scale.

266 analytical expressions for the frequency and dissipation shifts are derived for the entire range of p

267 Because the dissipation signal is related to the structure of the se

268 ent provides a promising route for low-power-dissipation spintronic devices.

269 d restoring transitions at vanishingly small dissipation strength in both single and multiphoton tran

270 en, to the equilibrium fluid by changing the dissipation strength.

271 es for velocity measurements and thus energy dissipation studies of single molecules in real time dur

272 To monitor thiocyclam metabolites in tomato, dissipation studies were carried out using a liquid chro

273 It reduces the influence of dissipations such as atomic spontaneous emissions and ca

274 derived ATP is limited by chloroplast energy dissipation systems, such as nonphotochemical quenching,

275 rcing the host cell membrane, and the energy dissipation that controls the timescale of the injection

276 of transcription initiation and supercoiling dissipation (the latter may either be diffusive or media

277 Due to enhanced areas for vapor dissipation, the PPy origami improves the water evaporat

278 ith a single transition appearing for static dissipation, the time-periodic counterpart undergoes [Fo

279 ments with analysis based on the fluctuation-dissipation theorem (FDT) to characterize origins of act

280 the completely general nonlocal fluctuation-dissipation theorem with nonlocal response of surface pl

281 detect a clear violation of the fluctuation dissipation theorem.

282 an-body midinfrared radiation to retain heat dissipation, thereby delivering around 6 degrees C cooli

283 ded noise are affected by reduced mechanical dissipation, thermal conductivity, and thermal capacity.

284 ngthening mechanism, but also enhance energy dissipation through controlled nano- and micro-fracture,

285 Based on a simple energy budget, the dissipation timescale for the eddy energy is three years

286 e identify simple and generic conditions for dissipation to prevent a quantum many-body system from e

287 The superballistic, low-dissipation transport is a generic feature of viscous el

288 sducers, sensors and filters by offering low dissipation, tunable coupling to diverse physical system

289 the head-the body part with the highest heat dissipation-under the feathers.

290 bove, 15%, with a 2-fold reduction in energy dissipation upon microtubule depolymerization.

291 all regimes and is consistent with Planckian dissipation. Using the extracted PLL parameters we repro

292 interesting regime in which Landau damping (dissipation via electron-hole pair excitation) is comple

293 arture from the usual situation where energy-dissipation via phonon emission outpaces energy gains du

294 ndant in the sediment incubations where fast dissipation was observed.

295 onsidering various forms of energy input and dissipation, we find that the water-driven cell-migratio

296 t-of-plane microwave fields and induce power dissipation, which is confirmed by the phase-field model

297 not largely impact the distribution of heat dissipation, while GBs of MoS(2) appreciably localize he

298 ontrol mechanisms underlying photoprotective dissipation, with implications for increasing biomass yi

299 reduced P-wavespeed may result from viscous dissipation within an incipient shear zone.

300 yered muPADs that takes into account viscous dissipation within the paper.