ライフサイエンスコーパス: dissipative

1 are utilized in products that are inherently dissipative.

2 Comparing it to the highly dissipative 1994 M(w) 8.3 Bolivia earthquake, the two ev

3 ctions and fails for very important class of dissipative (active) optical systems with cyclic gain an

4 We propose a dissipative allosteric model that generates dwell-time s

5 ing, in which coherent interactions dominate dissipative and decoherence effects.

6 pportunities for reproducing material-level, dissipative and diffusive kinetic phenomena at the struc

7 Unlike the celebrated dissipative and dispersive approximations of the Burgers

8 developed a simple model that explains both dissipative and dispersive changes produced by phononic

9 reviously supposed; rather, it appears to be dissipative and kinetically controlled.

10 We discuss the interplay between the dissipative and mass terms, the associated different reg

11 show that adaptive processes are necessarily dissipative, and continuous energy consumption is requir

12 m self-assembly" by subdividing systems into dissipative, and non-dissipative non-equilibrium states.

13 , inspiring studies on active matter, energy-dissipative assemblies, and programmable liquid construc

14 Dissipative assembly has great potential for the creatio

15 then review recent efforts towards man-made dissipative assembly of structures and how their unique

16 stitute a simple class of chemical fuels for dissipative assembly, taking advantage of their known re

17 be accompanied by a transition from largely dissipative atom-atom interactions to a regime where dis

18 romophores that are each linearly coupled to dissipative baths of harmonic oscillators, has become th

19 Higher waves associated with dissipative beaches increase the disturbance of strand s

20 issipative processes allow us to predict the dissipative behavior of the systems under different auxi

21 Dissipative behaviors in biology are fuel-driven process

22 ensemble experiments average over active and dissipative behaviours, preventing identification of dis

23 Synthetic demonstrations of dissipative biological systems such as actin filaments a

24 Remarkably, such a dissipative bonding is present even when the interaction

25 The dissipative bound states can be created and studied spec

26 Dissipative catalysis by synthetic molecular machines ha

27 city and directional amplification in driven-dissipative cavity arrays.

28 ng catalytic transformations dictated by the dissipative CDNs are demonstrated.

29 Thus, the model couples dissipative cell and tissue motion with kinetic equation

30 ion in powering oscillations in an otherwise dissipative cell-to-cell communication channel.

31 r practical entanglement distribution over a dissipative channel.

32 the destructive interference of two separate dissipative channels involving electron-like and hole-li

33 Dissipative chemical fueling has enabled access to stabl

34 e foundation for performance analysis of any dissipative chemical process.

35 modes, the adiabatic quantum mode (AQM), the dissipative classical mode [classical critical dynamics

36 e mechanotransduction channels to this least dissipative coherent mode, whereas the elastic horizonta

37 tely timed, elastic push-off helps to reduce dissipative collision losses at contralateral heelstrike

38 Dissipative colloidal materials use energy to generate a

39 tions, new sources of THz radiation, and low-dissipative computing.

40 nables permanent Rabi oscillations in driven-dissipative condensates of exciton-polaritons in semicon

41 to purified FeCh are organized in an energy-dissipative conformation and further show that FeCh can

42 ing systems, we introduce nucleic acid-based dissipative constitutional dynamic networks (CDNs) that

43 t consists in the quantum computation of the dissipative corrections to the unitary evolution of the

44 Chiral damping (alpha(c)), the dissipative counterpart of the Dzyaloshinskii Moriya Int

45 n two Kittel modes, accompanied by divergent dissipative coupling approaching the magnetic compensati

46 cial feature of these photonic structures is dissipative coupling between modes, via an interaction w

47 ors, particularly their ability to carry non-dissipative currents.

48 at rebinds to T(1) or T(2), resulting in the dissipative cyclic recovery of CDN "X".

49 est that a selection pathway based on energy-dissipative cycling could have driven the selective synt

50 ts each independently interacting with a non-dissipative decohering environment.

51 time was achieved via a technique involving dissipative decoupling of the single nuclear spin from i

52 concept of a quantum memristor as a quantum dissipative device, whose decoherence mechanism is contr

53 a variety of complex, high-resolution energy-dissipative devices.

54 on earlier efficient quantum algorithms for dissipative differential equations, we find and prove th

55 uously on the opposite sides of an expanding dissipative domain.

56 ving a high throughput rate, diffusional and dissipative dynamical factors must also be taken into co

57 sed on modern spectral theory of chaotic and dissipative dynamical systems, the associated low-freque

58 As a consequence, the dissipative dynamics is constrained by a robust addition

59 ntaneous emission-super-radiance(2)-with non-dissipative dynamics largely obscured by rapid atomic de

60 iubov modes can be effectively cooled by the dissipative dynamics of the cavity modes, generating ste

61 eraction as a basis to compute excited-state dissipative dynamics simulations on a fully passivated C

62 ty cooperates with the GDI to counteract the dissipative effect of a previously unappreciated pathway

63 ogy provides a powerful means of quantifying dissipative effects in temperature and chemical potentia

64 The existence of dissipative effects leads to the appearance of a "leaky

65 at higher concentration of Ag NPs due to non-dissipative effects unlike plasmon induced Joule heating

66 helicity among the length scales, triggering dissipative effects, and inducing fine-scale mixing.

67 Here by utilizing dissipative elements in a CMOS-compatible photonic platf

68 whereas microtubules contribute as resistive/dissipative elements.

69 uents and the triggering strands, orthogonal dissipative emerging catalytic transformations dictated

70 pture of the moons is then made permanent by dissipative energy loss (for example, gas drag) or plane

71 high to low light require the relaxation of dissipative energy processes, collectively known as non-

72 Compared with previous studies that involved dissipative entanglement of atomic ensembles or the appl

73 Our dissipative error correction scheme operates in a contin

74 d quasi-solitons, have been observed also in dissipative, "excitable" systems, either at finely tuned

75 asurement is even more challenging in driven-dissipative exciton-polariton condensates, since their n

76 the protocol distills rich information about dissipative excitonic dynamics, which appears nontrivial

77 d barrier to attachment is negligible, while dissipative factors in the quasi-2D confinement of the T

78 Here we experimentally demonstrate the dissipative Faraday instability induced by spatially per

79 librium is a key signature of bistability in dissipative first-order phase transitions.

80 many distinct catalytic actors can power the dissipative flux required to maintain a stable, far-from

81 n developing such a model is to evaluate the dissipative force caused by thermal quasiparticles in th

82 flect the mechanical coupling between energy dissipative forces and tissue-elastic properties) at low

83 the relative magnitude of thermal driving to dissipative forces in the fluid motion--becomes sufficie

84 imics of such structures, we herein describe dissipative formation of covalent basket cage CBC 5 by r

85 ized criticality in the dynamics of a driven-dissipative gas of ultracold potassium atoms: self-organ

86 llective role of long-ranged interactions in dissipative gases and can lead to novel designing princi

87 For the same adhesion, stiffer and less dissipative grains yield a less cohesive flow.

88 king time-reversal symmetry introduces a non-dissipative Hall component to the viscosity tensor, and

89 is work, we propose a nonequilibrium (driven-dissipative) hard-sphere model and formulate a hydrodyna

90 t of the nonequilibrium Mott transition in a dissipative Hubbard chain.

91 y amide side chains to create dynamic energy dissipative hydrogen bonds in a covalently cross-linked

92 hallow associative well explained the energy-dissipative hysteresis and dynamic, adaptive recovery.

93 structure is responsible for long-sought non-dissipative (hysteresis-free), linearly reversible and i

94 and operate complex active systems that are dissipative in nature, yet remain coherent indefinitely.

95 transport of radio-frequency signals can be dissipative in the presence of quasiparticle excitations

96 Dephasing processes, caused by non-dissipative information exchange between quantum systems

97 tre scale is a key step towards fast and low-dissipative information processing.

98 Chiral asymmetry might help to minimize dissipative interaction between entering, recirculating

99 dissipation imaging quantitatively isolates dissipative interfacial interactions from topography, pr

100 issolving/swelling films that form an energy-dissipative, interfacial layer.

101 alized introduction of ions, which through a dissipative ion exchange process, converts quaternary am

102 Dissipative Kerr soliton (DKS) featuring broadband coher

103 Dissipative Kerr soliton (DKS) frequency combs-also know

104 Dissipative Kerr soliton (DKS) microcomb has emerged as

105 Like other optical solitons, the dissipative Kerr soliton can radiate power as a dispersi

106 Dissipative Kerr soliton generation using self-injection

107 e, and report the discovery of heteronuclear dissipative Kerr soliton molecules.

108 are reconstructed with 740 fs resolution and dissipative Kerr soliton transition dynamics, in which a

109 Dissipative Kerr solitons are self-sustaining optical wa

110 copy to image the dynamics of slowly evolved dissipative Kerr solitons in a microresonator.

111 tudy the dynamic waveforms of slowly evolved dissipative Kerr solitons in an ultrahigh-Q microresonat

112 integrated comb systems is the formation of dissipative Kerr solitons in coherently pumped high-qual

113 hat we observe share several properties with dissipative Kerr solitons, providing a first step toward

114 and agonist molecules modifies the observed dissipative landscapes.

115 hat the system is self-adjusting to minimize dissipative loss during the 'read' and 'write' operation

116 erence, or scattering with a typically small dissipative loss.

117 particles offer the opportunity for reducing dissipative losses and achieving large resonant enhancem

118 y (ACE) remains fundamentally constrained by dissipative losses and intrinsic nonlinear effects.

119 A third system demonstrating transient, dissipative, luminescence properties of a reaction modul

120 ipative phonons behave in a coherent and non-dissipative manner.

121 Driven-dissipative many-body systems are ubiquitous in nature a

122 or guiding rules for this highly hysteretic, dissipative material.

123 Despite advances in creating dissipative materials with transient properties, such as

124 an boost mechanosensing on cells cultured on dissipative matrices.

125 ing of two layers: an adhesive surface and a dissipative matrix.

126 monstrated, as expected, that nonequilibrium dissipative measurements obtained here gave larger energ

127 f the microwave resonator and heating of the dissipative mechanical bath.

128 irection or can provide an environment where dissipative mechanisms such as spontaneous emission are

129 detailed studies of normal-fluid turbulence, dissipative mechanisms, and unsteady/oscillatory flows.

130 enna even in high light and switch on energy-dissipative mechanisms, cells in high CO2 reduce the amo

131 c devices it is often susceptible to various dissipative mechanisms, which are difficult to study dir

132 d the electromagnetic response of a physical dissipative medium in a finite real-frequency bandwidth.

133 ry chlorophyll (bridge) that interact with a dissipative medium of protein and solvent degrees of fre

134 hampered practical implementations have been dissipative metal losses, but the efficient use of optic

135 The long-time steady state of our driven-dissipative model exhibits thus all the characteristics

136 nite chain resulting in localized lasing and dissipative modes at each end of the chain.

137 This general problem-self-assembly of dissipative molecular networks-is also important in unde

138 t use of hydrogen bonds and the emergence of dissipative molecular stick-slip deformation leads to si

139 ing chemical potential to repeated cycles of dissipative nanomechanical motion.

140 However, the highly dissipative nature of soft materials intrinsically limit

141 The dissipative nature of the polymer readily damps linear w

142 for each of the states, with a focus on non-dissipative non-equilibrium states found in one-dimensio

143 ubdividing systems into dissipative, and non-dissipative non-equilibrium states.

144 ocus has shifted to kinetically trapped (non-dissipative non-equilibrium) structures that heavily dep

145 au), exhibiting dissipationless (chiral) and dissipative (non-chiral) edge conduction, respectively.

146 al NLSE breather solutions can describe such dissipative nonlinear dynamics, our results may impact t

147 The non-dissipative nonlinearity of Josephson junctions(1) conve

148 formation from a light-harvesting state to a dissipative one.

149 tool to induce phase transitions beyond the dissipative ones and tune their universality class.

150 )L(2) and nicking enzyme Nt.BbvCI, undergoes dissipative orthogonal transitions to CDN "Y" and back o

151 ften generate precise responses by involving dissipative out-of-thermodynamic-equilibrium processes i

152 Following the significance of dissipative, out-of-equilibrium biological processes con

153 y spatially periodic zig-zag modulation of a dissipative parameter of the system-spectrally dependent

154 A dissipative particle dynamics (DPD) approach, combined w

155 An optimized Dissipative Particle Dynamics (DPD) model with simple sc

156 coarse-grained molecular dynamics (CGMD) and dissipative particle dynamics (DPD) to predict the stati

157 imulation method based on the integration of dissipative particle dynamics (DPD), smoothed particle h

158 a unique whole-cell model of the RBC, using dissipative particle dynamics (DPD).

159 Among other methods, dissipative particle dynamics and the lattice Boltzmann

160 Dissipative particle dynamics cast in a new membrane for

161 Dissipative particle dynamics simulations of a coarse-gr

162 Herein we perform dissipative particle dynamics simulations to elucidate t

163 nd introducing such a proliferation model in dissipative particle dynamics simulations, we recover th

164 y of PLPs for fibrin fibres, as evidenced by dissipative particle dynamics simulations.

165 We employed dissipative particle dynamics to extend a validated mult

166 Based on dissipative particle dynamics, we develop a multiscale m

167 n which proteins are embedded, with a hybrid dissipative particle dynamics-Monte Carlo method.

168 ES, using computational simulations based on dissipative particle dynamics.

169 and nonequilibrium physics: can the evolved dissipative pathways that facilitate biomolecular functi

170 vide evidence that the membrane enhances two dissipative pathways, one of which is a previously uncha

171 and time is required to characterize driven-dissipative phase transitions and enable the investigati

172 neering, dissipative quantum computation and dissipative phase transitions.

173 accomplished making typically incoherent and dissipative phonons behave in a coherent and non-dissipa

174 eal-time insight and direct visualisation of dissipative photophysics, and illustrate this with an ex

175 We develop a versatile method for dissipative preparation of incompressible many-body phas

176 The bound state arises in a dissipative process and manifests itself as a stationary

177 Fracture is a highly dissipative process in which much of the stored elastic

178 s: coronal mass ejections from an ideal (non-dissipative) process, whereby the energy release does no

179 Kinetic simulations of the dissipative processes allow us to predict the dissipativ

180 changes to their strength and dispersion if dissipative processes are included by Langevin dynamics.

181 This work shows how dissipative processes can be used to systematically tune

182 thoroughly understood is how the omnipresent dissipative processes enter the critical dynamics near a

183 e reduction of maximum wave height caused by dissipative processes in shallow waters.

184 roposed method takes into account random and dissipative processes in the system, does not require a

185 ach enabling inclusion of both adiabatic and dissipative processes into the critical dynamics on the

186 ping in both amplitude and phase, we unravel dissipative processes of electronic coherences in the mo

187 stematically characterizes both coherent and dissipative processes of the probed chromophores is desi

188 Such dissipative processes provide a route toward structures

189 The active movements are accompanied by dissipative processes that can be conceptually understoo

190 I review here the dissipative processes that determine the critical scales

191 motion of colloidal particles for studies of dissipative processes, providing insight into soft matte

192 -reversal symmetry, which is the hallmark of dissipative processes, remains a challenge in the absenc

193 terials that-when coupled with non-radiative dissipative processes-allow the conversion of radiative

194 ffusion-based pattern instability and allied dissipative processes.

195 orce microscopy has been used to analyze the dissipative properties of chemically similar regions of

196 cean on Europa, and may guide studies of the dissipative properties of stars and Jupiter-like planets

197 lly as a result of the interplay between the dissipative properties of the environment and the animal

198 not straightforward to explicitly model the dissipative property of existing active particles driven

199 obstacle, we develop a quantum algorithm for dissipative quadratic n-dimensional ordinary differentia

200 Dissipative quadratic solitons (DQSs), enabled by nonlin

201 step towards dissipative state engineering, dissipative quantum computation and dissipative phase tr

202 ical critical dynamics mode (CCDM)], and the dissipative quantum critical mode (DQCM).

203 However, while non-dissipative quantum dynamics is described in detail, the

204 We go beyond dissipative quantum state engineering approaches towards

205 ry accurately predicts the rate of many-body dissipative quantum tunnelling subject to the polaron ef

206 ied in Fe-Co Prussian blue analogues using a dissipative quantum-mechanical model of a cobalt ion cou

207 In addition, using a combination of dissipative quartz crystal microbalance measurements and

208 the rate of coherent coupling exceeding the dissipative rates of the atom and the cavity.

209 ields programmed reconfiguration patterns of dissipative reaction cycles.

210 uel-driven reconfiguration, are coupled to a dissipative reaction module that triggers the reconfigur

211 Activator consumption by a coupled dissipative reaction network leads to autonomous cycling

212 s have been indicated as site(s) of the heat-dissipative reactions.

213 With multiple rounds of this energy-dissipative recycling, we show that all-3',5'-linked dup

214 n which large (small) foredunes are found on dissipative (reflective) beaches.

215 ally generated distortion products indicated dissipative relative motions.

216 oupling between the two-qubit register and a dissipative reservoir.

217 cloud and clear air properties persisting to dissipative scales (<1 centimeter).

218 By means of an example of a biological dissipative self-assembled material, the unique concepts

219 The transition from dissipative self-assembled structures for fast oscillati

220 ins a challenge to introduce into artificial dissipative self-assemblies.

221 Recent experiments in dissipative self-assembly also demonstrated that by open

222 election during catalysis, self-replication, dissipative self-assembly and synthetic molecular machin

223 However, design strategies for dissipative self-assembly are limited by a lack of funda

224 The use of dissipative self-assembly driven by chemical reaction ne

225 Dissipative self-assembly is the emergence of order with

226 Although dissipative self-assembly is ubiquitous in nature, where

227 This work proposes a novel route for dissipative self-assembly via the oscillation of interpa

228 be toggled between no assembly, fuel-driven dissipative self-assembly, and a state in which the syst

229 f fuels, light, the original fuel of natural dissipative self-assembly, is fundamentally important bu

230 Dissipative self-assembly, one of fundamentally importan

231 In dissipative self-assembly, precursors are converted into

232 Dissipative self-assembly, which relies on continuous en

233 Dissipative self-assembly, which requires a continuous s

234 The reactive and dissipative sensing methods, characterized by light-anal

235 show that a hair bundle breaks into a highly dissipative serial arrangement of stereocilia at distort

236 lated matter in both coherent and engineered dissipative settings.

237 We further propose that dissipative signals obtained by measuring the total abso

238 are recently merged to the concept of vector dissipative soliton (VDS), viz.

239 Two fundamental laser physics phenomena--dissipative soliton and polarisation of light are recent

240 tor, and consequently causes perturbation to dissipative soliton formation and amplitude modulation t

241 m for optical frequency comb generation, via dissipative soliton formation.

242 n-managed (DM) soliton (stretched-pulse) and dissipative soliton mode-locking regimes can be reliably

243 ation predicts the existence of stable 2 mum dissipative soliton solutions with pulse energy over 10

244 Magnetic droplets, a type of non-topological dissipative soliton, can be nucleated and sustained in n

245 ecent discovered new mode-locking mechanism--dissipative soliton--has successfully improved the pulse

246 Dissipative solitons (DSs) are multi-dimensionally local

247 Dissipative solitons are fundamental wave-pulses that pr

248 Dissipative solitons are self-localized structures that

249 otection, identify exceptional points in the dissipative spectrum, and reveal temperature-dependent c

250 iffusivity of CO(2), an acidic gas, from the dissipative spread of photolytically uncaged H(+) ions a

251 capability to undergo transformation into a dissipative state by conformational change and it was su

252 tate of two qubits represents a step towards dissipative state engineering, dissipative quantum compu

253 The transition into the dissipative state is associated with a twist in the conf

254 This dissipative state is strictly dependent on the accumulat

255 al states different from those possible with dissipative state preparation or conventional projective

256 troscopy, performed on purified LHCII in the dissipative state, shows that energy is transferred from

257 thermodynamic equilibrium (or from other non-dissipative states).

258 We discover the existence of two dissipative states.

259 Dissipative steady-state structures were formed when the

260 direct evidence of slow, distance-dependent dissipative stress propagation in response to external m

261 ealized through the adaptive property of the dissipative structure of the driven ferromagnetic system

262 The cluster is a dissipative structure similar to self-organized Rayleigh

263 n economy is viewed as an out-of-equilibrium dissipative structure that can only be maintained with a

264 The three vortex rings form a coherent, dissipative structure.

265 Some of the dissipative structures (dimers, fibers, and honeycombs)

266 d fibre lasers, including a broad variety of dissipative structures and self-organization effects, ha

267 c-scale, tribo-ceramic films associated with dissipative structures formation are discovered under ex

268 physiological conditions, forming a class of dissipative structures that trade metabolic energy for i

269 oft grippers, continuum manipulators, energy-dissipative structures, and foldable metamaterials.

270 ergent turbulence, which transfers energy to dissipative structures.

271 s are translated into distinct intracellular dissipative structures.

272 metabolism self-organizes into two types of dissipative structures: chemical oscillations and travel

273 ccessible external interactions (coherent or dissipative) such that a chosen target reaches a desired

274 of disorder-induced localisation in a driven-dissipative system.

275 developed energetic variational approach to dissipative systems allows mathematically consistent tre

276 Nonequilibrium phase transitions in open dissipative systems can be described as instabilities in

277 tinct bubble properties, suggests that these dissipative systems have attractors that control the sta

278 s of the dynamical encircling of EPs in open dissipative systems have been explored in optics and pho

279 eakthroughs introduced a description of open dissipative systems in terms of non-Hermitian quantum me

280 of interface pattern selection in nonlinear dissipative systems is critical in many fields of scienc

281 Dissipative systems may provide a proper platform to imp

282 The design of dissipative systems, which operate out-of-equilibrium by

283 a unique path to study the physics of driven-dissipative systems.

284 z-Thouless-like phase order survives in open-dissipative systems.

285 f quantum optical states in nonlinear driven-dissipative systems.

286 f unstable periodic orbits underlie chaos in dissipative systems; accordingly, the new method searche

287 nservative force field plus two asymmetrical dissipative terms.

288 The basic theory for dissipative tip-sample interactions is introduced to mod

289 uture perspectives of the field in designing dissipative transient CDNs, CDNs-guided transcription/tr

290 ose, Fe(3+)-CMC, redox-active gel exhibiting dissipative, transient stiffness properties is introduce

291 ation of the Fe(2+)-CMC matrix, leads to the dissipative, transient stiffness, functional matrix.

292 th time is seen, suggesting a time-dependent dissipative transport mechanism.

293 Dissipative two-level systems (TLS) have been a long-sta

294 ctral density of random processes in an open dissipative two-particle system was developed.

295 s wavelength either reside within the highly dissipative two-photon regime in silicon-based optical d

296 of high severance taxes on virgin materials) dissipative uses of the above type.

297 rent and oscillatory evolution constitutes a dissipative version of a quantum time crystal.

298 dynamical lattices, high anharmonicity, and dissipative vibrations very similar to the 3D AMX(3) per

299 The fastest and least dissipative way of switching the technologically most im

300 Thus, the source process was dissipative, which is consistent with the observed slow