ライフサイエンスコーパス: entanglement

1 be engineered to assist in the formation of entanglement.

2 n to provide a source of multimode N00N-type entanglement.

3 ion to another through the agency of quantum entanglement.

4 nversion of coherence into many-body quantum entanglement.

5 rations, classical communication, and shared entanglement.

6 ng and exploration of the physics of quantum entanglement.

7 ks for long-distance distribution of quantum entanglement.

8 polarization mode dispersion (PMD) degrades entanglement.

9 nce between ordered nanostructure and fibril entanglement.

10 e-to-optical photon converters that preserve entanglement.

11 test a remedy to recover the high degree of entanglement.

12 opological order and high degrees of spatial entanglement.

13 for scalable generation and distribution of entanglement.

14 size inputs may require unbounded amounts of entanglement.

15 ore different paths, the cell needs to avoid entanglement.

16 ces of attosecond light having squeezing and entanglement.

17 of a finite correlation witnessing infinite entanglement.

18 incrementally increase the dimensionality of entanglement.

19 rials with multiple metal centres and strong entanglement.

20 s a key process that leads to a spin-orbital entanglement.

21 sources of quantum information processing is entanglement.

22 geometry of the setup that give rise to the entanglement.

23 tical tests which can detect the presence of entanglement.

24 tate-of-the-art OLCs(1-4) through the use of entanglement.

25 synergistic mechanism to resolve topological entanglements.

26 kers becomes smaller than the length between entanglements.

27 ng relaxation time due to the confinement of entanglements.

28 ance for the control of systems with complex entanglements.

29 stead characterized by intricate patterns of entanglement(3,4).

30 ts(2,3) because they enable on-demand remote entanglement(4), coherent control of over ten ancillae q

31 are classically impossible has made quantum entanglement a powerful resource for the development of

32 cles presents itself as a useful resource of entanglement accessible for practical applications.

33 nonzero thermodynamic entropy, which is the entanglement accumulated during the dynamics.

34 ange quantum networks is the distribution of entanglement across many individually controllable qubit

35 Optical networks that distribute entanglement among various quantum systems will form a p

36 ow ab initio modelling, machine learning and entanglement analysis can enable simulations which provi

37 underlying both resource theories of quantum entanglement and classical secret key.

38 upper bound based on the relative entropy of entanglement and devising a dimension-independent techni

39 permanent crosslinking network through chain entanglement and DNA hybridization, resulting in shear-t

40 Entanglement and entropy are key concepts standing at th

41 antum information, efficient distribution of entanglement and generation of completely secure keys.

42 rge quantum state space through controllable entanglement and interference.

43 stic behavior of coherence resembles that of entanglement and is opposite to that of discord.

44 um spin liquid state, which shows long-range entanglement and no magnetic ordering down to 0 K.

45 vel explorations in microwave-optical photon entanglement and quantum sensing mediated by gigahertz p

46 We show that G3BP condensates impede RNA entanglement and recruit additional client proteins that

47 st Greenland narwhals after release from net entanglement and stranding.

48 s a state of matter characterized by quantum entanglement and the absence of any broken symmetry.

49 tum interference effects associated with the entanglement and this is not observable with classical e

50 complex microenvironments, where it leads to entanglement and ultimately fragmentation of the cell bo

51 of local information into many-body quantum entanglements and correlations distributed throughout an

52 ides some of the earliest records of plastic entanglement, and is the first to confirm a significant

53 novo Topoisomerase II (TopoII)-dependent re-entanglements, and complete failure in chromosome segreg

54 The configurations of these entanglements appear to play a key role in determining t

55 The phenomena of sudden birth and death entanglement are found.

56 y fluctuations, we find that interchromosome entanglements are minimized for a certain "optimal" loop

57 Typical confined-extending surrounded by one entanglement area is proposed to describe the physical s

58 works and relies on high-dimensional quantum entanglement as a core resource.

59 that waveguiding can arise from rich atomic entanglement as a quantum many-body effect and elucidate

60 viding information on electron coherence and entanglement at the individual particle level.

61 Here we demonstrate entanglement-based QKD between two ground stations separ

62 ecurity risks, which can be avoided by using entanglement-based QKD, which has inherent source-indepe

63 emission above its excitation energy due to entanglement between atomic quantum system and electroni

64 provide an ideal test bed for investigating entanglement between complex spin systems.

65 ngular transformation in the patterns of the entanglement between local moments and conduction electr

66 op a witness which allow them to demonstrate entanglement between millions of atoms in a solid-state

67 nstructing a second chip, which measures the entanglement between multiple distant pairs of simulated

68 , the same technique can be used to generate entanglement between oscillators in the quantum regime.C

69 the input, and we experimentally demonstrate entanglement between over two hundred ensembles, each co

70 ion of the superconducting qubit and quantum entanglement between qubit pairs.

71 e open up the possibilities to study quantum entanglement between reaction products and ultracold rea

72 provide evidence for the existence of hidden entanglement between spin and momentum in the antiperovs

73 ontrol of the nuclear spin qubit, as well as entanglement between the nuclear and electron spins.

74 Here we demonstrate entanglement between the rotational states of a (40)CaH(

75 d control photons, and confirm deterministic entanglement between the signal and control modes by ext

76 a key step towards this vision, and generate entanglement between two propagating optical modes, by c

77 s how the GLN method can be applied to study entanglement between two structures none of which are cl

78 icant progress has been achieved and genuine entanglement between up to 2900 atoms was reported.

79 ur results indicate that, during interphase, entanglements between chromosomes and chromosomal domain

80 Entanglements between helices can aid gelation by produc

81 the SQL by engineering quantum correlations (entanglement) between atoms(9-20) has been demonstrated

82 Understanding quantum thermalization through entanglement build up in isolated quantum systems addres

83 kably, certain correlations not only witness entanglement, but they give quantitative bounds on the m

84 ctions necessitate a means to improve remote entanglement by local quantum operations.

85 The concept of entanglement by path identity itself is a general scheme

86 Such a framework, termed entanglement by path identity, exhibits a high degree of

87 Quantum theory predicts that entanglement can also persist in macroscopic physical sy

88 cal motivations for studying whether quantum entanglement can exist in macroscopic systems.

89 shows that significant amount of mechanical entanglement can indeed be obtained by balancing the opp

90 Scrambling and entanglement can reconcile seemingly unrelated behaviors

91 While entanglement can reside in any photonic degree of freedo

92 High molecular weight, thus sufficient chain entanglement, combined with a small-amount dynamic CB[8]

93 eloped a novel method to quantify chromosome entanglement complexity in 3D reconstructions obtained f

94 one are not sufficient to obtain the reduced entanglement complexity observed in 3D reconstructions.

95 ity (constitutional chirality) via molecular entanglement (conformation) to liquid-crystal (centimetr

96 he impact of coupling factor of networks and entanglement degree in quantum games on the evolutionary

97 Entanglement, determined by spin and orbital degrees of

98 We realize entanglement distillation on a quantum network primitive

99 Our method provides efficient entanglement distributing with respect to the actual sta

100 Long-distance entanglement distribution can be realized using quantum

101 Here we define the method of opportunistic entanglement distribution for the quantum Internet.

102 ellite-based QKD, but so far satellite-based entanglement distribution has not been efficient(23) eno

103 derate-complexity solution for high-fidelity entanglement distribution in experimental quantum Intern

104 lement transmission and relevant measures of entanglement distribution in quantum networks.

105 ndamental problem of the quantum Internet is entanglement distribution.

106 ty to govern DNA topology and resolve strand entanglements during fundamental molecular processes, th

107 ns, leads to a complete understanding of the entanglement dynamics in the space-time scaling limit.

108 Alas, an exact computation of the entanglement dynamics was available so far only for noni

109 We further show that cross-links dominate entanglement dynamics when the length between cross-link

110 This entanglement enables accomplishing a task, violation of

111 inding interference processes from which the entanglement entropy and Hubbard interactions are quanti

112 scaling of various quantities (concurrence, entanglement entropy, magnetic and fidelity susceptibili

113 n is consistent with a logarithmic growth of entanglement entropy, the hallmark of many-body localiza

114 antum thermalization linked to the growth of entanglement entropy.

115 irs of simulated spins, as well as the block entanglement entropy.

116 an elucidate connections between scrambling, entanglement, ergodicity and quantum chaos (butterfly ef

117 Therefore, understanding the entanglement evolution unveils how thermodynamics emerge

118 at the standard quasiparticle picture of the entanglement evolution, complemented with integrability-

119 amics projected onto states with appropriate entanglement, extending previous results about initial e

120 ctated by combined functional and structural entanglement factors.

121 d the predictability of the evolution of the entanglement fidelities.

122 photon extraction efficiency, high degree of entanglement fidelity and photon indistinguishability ha

123 le-photon extraction efficiency of 0.85(3)), entanglement fidelity of 0.88(2), and indistinguishabili

124 The entanglement fidelity of our teleported CNOT is in the i

125 ity, fluctuation attributes, and dynamics of entanglement flow in entangled network structures.

126 dynamics of entangled network structures and entanglement flow in the quantum Internet.

127 ces with a potential for generating "useful" entanglement for the purpose of quantum computing and th

128 for rigorously quantifying high-dimensional entanglement from extremely limited data.

129 s paper, this fact is used for extraction of entanglement from independent particles unaffected by an

130 oordination was also found to translocate an entanglement from one region of a knotted molecular stru

131 e formation and unraveling of conformational entanglements from newly incorporated monomers, whose ke

132 The photon-entanglement gates of the second type are created by dua

133 t isolated quantum systems(1) with low-error entanglement gates operated within tens of microseconds

134 and deterministic quantum state transfer and entanglement generation between remote nodes with a high

135 Our method for photonic entanglement generation may have potential for developin

136 he dynamics of a spin chain and maximise the entanglement generation.

137 he mechanical mean values detrimental to the entanglement generation.

138 t an experimental demonstration of a general entanglement-generation framework, where the form of the

139 reads to determine the shortest path via the entanglement gradient coefficient, which describes the f

140 We define the entanglement-gradient routing scheme for quantum repeate

141 We show that the entanglement growth rate is related to the Kolmogorov-Si

142 nt, extending previous results about initial entanglement growth to all times.

143 Quantum entanglement has been shown to imply correlations strong

144 We find that the degree of entanglement has no effect on the quantum control of the

145 Though knotting and entanglement have been observed in DNA and proteins, the

146 f intense research with the observation that entanglement holds interesting information about quantum

147 roach for generating steady-state mechanical entanglement in a coupled optomechanical system.

148 and optimisation of the extensive growth of entanglement in a spin chain, and opens up the use of ph

149 , Zarkeshian et al. demonstrate multipartite entanglement in an atomic frequency comb storing a singl

150 ue offers a universal method for quantifying entanglement in any large quantum system shared by two p

151 Our results clarify the role of multipartite entanglement in ensemble-based quantum memories and demo

152 ality rates associated with ship strikes and entanglement in fishing gear.

153 tructure prediction, properties of polymers, entanglement in fluids and fields, etc.

154 Generating quantum entanglement in large systems on timescales much shorter

155 s a significantly faster technique to detect entanglement in lasso proteins in comparison with other

156 Entanglement in macromolecules is an important phenomeno

157 limited experimental control.The presence of entanglement in macroscopic systems is notoriously diffi

158 The nature of entanglement in many-body systems is a focus of intense

159 This transition shows that entanglement in many-body systems may be enhanced under

160 As a step towards a fuller exploitation of entanglement in other degrees of freedom, in this work w

161 oposed to form due to a mix of soil particle entanglement in root hairs and the action of adhesive ro

162 structural transformation, and spin-lattice entanglement in strongly correlated materials.

163 ions via ions, a refined characterization of entanglement in terms of knotoids, the identification of

164 py has a key role in this process, injecting entanglement in the form of triplet resonating valence b

165 investigate the role played by the backbone entanglement in the process.

166 Our work could enable studies of photonic entanglement in the transverse modes of a fibre and coul

167 Instead of exploring quantum entanglement in the two-mode interferometers, a single b

168 However, entanglement in these systems has only been experimental

169 tic neutron scattering enables us to portray entanglement in weakly coupled molecular qubits and to q

170 potential causes for record numbers of whale entanglements in the central California Current crab fis

171 example by topoisomerase II, would result in entanglements, increased mixing at domain interfaces and

172 Quantum entanglement involving coherent superpositions of macros

173 Fabry-Perot resonators will allow multimode entanglement involving electromagnetic, mechanical, and

174 Quantum entanglement is a building block of the entangled quantu

175 arios, the distribution mechanism of quantum entanglement is a critical and emerging issue in quantum

176 Entanglement is a crucial resource for quantum informati

177 Quantum entanglement is arguably the cornerstone which different

178 The resulting entanglement is certified by constructing a second chip,

179 However, multiparty entanglement is generally fragile and difficult to quant

180 tangled photon pairs, however, the degree of entanglement is maintained when photon pairs are distrib

181 e contains further entanglement.Multipartite entanglement is of both fundamental and practical intere

182 angled photon, we find that its polarization entanglement is preserved and non-locally correlated wit

183 Entanglement is simultaneously responsible for the diffi

184 Entanglement is the key resource for measurement-based q

185 Entanglement is the powerful and enigmatic resource cent

186 rate is achievable using finite-dimensional entanglement is undecidable.

187 Quantum entanglement is usually considered a fragile quantity an

188 re overhand knots of Lambda- or Delta-handed entanglement) is reminiscent of the chiron approach of u

189 We further demonstrate entanglement manipulation by using GHZ states to distrib

190 intermediate coupling strengths multipartite entanglement may form between qubits and between higher

191 ies to any space-time correlations violating entanglement monogamy, such as those arising in black ho

192 linear dynamics is needed to avoid violating entanglement monogamy.

193 at each individual ensemble contains further entanglement.Multipartite entanglement is of both fundam

194 d photon pairs maintain their high degree of entanglement, no matter what type of spatial modes they

195 at a ferromagnetic QCP suggests that quantum entanglement-not the destruction of antiferromagnetism-i

196 The mechanical entanglement obtained in the stationary regime is strong

197 Exactly quantifying the entanglement of an unknown system requires completely de

198 t that condensation promotes the topological entanglement of chromatin fibers and the inhibition of f

199 ssential player in the simplification of the entanglement of chromatin fibers.

200 lls to provide insights into the topological entanglement of chromatin.

201 ar envelope, helps to reduce the topological entanglement of chromosomes.

202 long-range qubit coupling and the long-range entanglement of electrons in semiconductor quantum dots.

203 its validity versus the directly calculated entanglement of formation, suggesting possible experimen

204 Entanglement of mental processes with environmental and

205 We explore the entanglement of multipartite and multidimensional system

206 Entanglement of nanoscale components in the network reli

207 y (TS) plots show the strong preservation of entanglement of photons propagating in brain tissue.

208 ch physics may be realized as critical Kondo entanglement of spin and charge and probed with optical

209 Entanglement of states is one of the most surprising and

210 atial superposition and show how it leads to entanglement of temporal orders between time-like events

211 han spherical particles, probably due to the entanglement of the angular particles in the pores.

212 achines to keep track of the dense many-body entanglement of the gas molecules.

213 e Rabl configuration) that the complexity of entanglement of the genome is comparable to that of the

214 of the cavity modes, generating steady-state entanglement of the mechanical modes.

215 vicinity of the invagination and because of entanglement of the meshwork due to its dendritic struct

216 density interaction determine the long-range entanglement of the model which possesses "restricted pa

217 tituent fibers and the density and degree of entanglement of the network.

218 Variables that describe the degree of entanglement of the surfactant-linked polymer chain web

219 We develop an interferometer to prove entanglement of these distinguishable properties of the

220 acoustic wave phonons, enabling the quantum entanglement of two superconducting qubits.

221 rs the irreversible formation of topological entanglements of the fibers resulting in an entangled wa

222 6,456 measurements are needed to certify an entanglement-of-formation of 7.11 +/- .04 ebits shared b

223 y, maximal Bell-correlation, and concurrence entanglement] of the two qubits are explored.

224 ould enable the exploration of multiparticle entanglement on an extended quantum network.

225 The generation of entanglement on an optical-clock transition and operatio

226 s pave the way towards long-lived engineered entanglement on an optical-clock transition(13) in tailo

227 antum memories with photons for photon-based entanglement operations in a quantum network.

228 puters the main challenge is to realize fast entanglement operations in crystals made up of many ions

229 sequences that are readily observed, such as entanglement or starvation.

230 s, thus dispensing with quantum nonlocality, entanglement, or even discord between the players' input

231 rs in the forms of time-bin and polarization entanglement over a 1-km-long FMF.

232 lity to transfer quantum states and generate entanglement over distances much larger than qubit lengt

233 Distributing entanglement over long distances using optical networks

234 aviour in an MBL system requires probing its entanglement over space and time(4,5,7), which has prove

235 gular momentum conversion, spin-orbit hybrid entanglement, particle manipulation and transportation,

236 e" that illustrates the conundrum of quantum entanglement per the Bell spin states for the "general r

237 The entanglement persists at room temperature, where we veri

238 strings of hundreds of photons in which the entanglement persists over five sequential photons.

239 ered Bose-Hubbard chain and characterize its entanglement properties through particle fluctuations an

240 ir unique features such as superposition and entanglement, quantum computers promise to efficiently d

241 roperties of quantum repeaters and theory of entanglement rate maximization in an entangled network s

242 ework of noise-scaled stability analysis and entanglement rate maximization is conceived for the quan

243 anglement swapping method that maximizes the entanglement rate of the quantum repeaters at the differ

244 We prove the entanglement rates for the different entanglement swappi

245 sses "restricted patterns" of the long-range entanglement realized in corresponding string-net models

246 a thermal reservoir, can quickly destroy the entanglement resource.

247 nagers, and scientists could mitigate future entanglement risk by developing climate-ready fisheries

248 arkable quantum phase transition whereby the entanglement scaling changes from area law into extensiv

249 Topological entanglements severely interfere with important biologic

250 ntum networks hinges on high-quality quantum entanglement shared between network nodes.

251 First, we find that quantum entanglement shared between senders can substantially bo

252 f spatial channels and degrees of freedom of entanglement should be carefully considered.

253 quantify the distance between them using the entanglement spectrum.

254 The entanglement structure of thermofield double and critica

255 nder certain magnetic conditions a series of entanglement sudden-deaths and revivals occur between th

256 bed for fundamental tests of quantum science.Entanglement swapping in high dimensions requires large

257 To overcome this, entanglement swapping may be used to generate remote qua

258 We determine the optimal entanglement swapping method that maximizes the entangle

259 en different anti-symmetric states, and thus entanglement swapping occurs for several thousand pairs

260 Here we demonstrate entanglement swapping of multiple orbital angular moment

261 Here the authors demonstrate entanglement swapping of multiple spatial modes of light

262 We define the term of entanglement swapping set that models the status of quan

263 ove the entanglement rates for the different entanglement swapping sets and noise levels.

264 omplete entanglement swapping sets, complete entanglement swapping sets and perfect entanglement swap

265 te of the quantum repeaters at the different entanglement swapping sets as function of the noise of t

266 ve the stability properties for non-complete entanglement swapping sets, complete entanglement swappi

267 plete entanglement swapping sets and perfect entanglement swapping sets.

268 ability of a quantum repeater implies stable entanglement swapping with the boundness of stored densi

269 nditional teleportation of spin eigenstates, entanglement swapping, and gate teleportation.

270 mposite knots are assembled by combining two entanglement synthons (of the same chirality for a grann

271 ts of specific handedness as three-crossing "entanglement synthons".

272 light provide an avenue for high-dimensional entanglement, the ability to transport such quantum stat

273 vel of chromosome compaction with suppressed entanglements; the transition to the metaphase state req

274 Furthermore, we gauge the level of entanglement through the concurrence measure and show th

275 ulations, contributed to the exacerbation of entanglements throughout the marine heatwave.

276 re of such dynamics is the growth of quantum entanglement to an amount proportional to the system siz

277 nipulation by using GHZ states to distribute entanglement to distant sites in the array, establishing

278 s, while microwave resonators can extend the entanglement to macroscopic distances.

279 We present a retroactive assessment of entanglements to demonstrate that cooperation of fishers

280 ossess remarkable control of the folding and entanglement topology of long and flexible chromosomal D

281 to perform the locality-constrained tasks of entanglement transformation and its classical analog of

282 rics are derived from the characteristics of entanglement transmission and relevant measures of entan

283 We characterise the multipartite entanglement using an entanglement witness based upon th

284 y fails to eliminate detrimental topological entanglements, utilization of the information stored in

285 Hence we envision long-range nuclear-nuclear entanglement via electron shuttling(3).

286 red Bose-Hubbard system and characterize its entanglement via its multi-point quantum correlations.

287 tion of both probabilistic and deterministic entanglements which can be formed by disulfide bonds and

288 tanding this phenomenon lies in the system's entanglement, which is experimentally challenging to mea

289 experimental measure of continuous variable entanglement, which relies on the detection of only one

290 Since quantum entanglement will be fundamental to any future quantum n

291 Stable transmission of polarization-encoded entanglement with a high fidelity of 91% is achieved, fa

292 t for quantum repeaters, we demonstrate that entanglement with flying optical qubits can be stored in

293 ssibility to certain classes of multipartite entanglement with limited experimental control.The prese

294 at entropy growth proceeds from the system's entanglement with the environment.

295 hing polymer network in situ, in topological entanglement with the pre-existing polymer networks of t

296 emain associated through periodic mechanical entanglements within each sheet.

297 ameter of the polymer chains, diluting their entanglements without markedly increasing stiffness.

298 erise the multipartite entanglement using an entanglement witness based upon the structure factor and

299 We develop an entanglement witness for quantifying the number of genui

300 We improve an entropic, quantitative entanglement witness to operate directly on compressed e