ライフサイエンスコーパス: degeneracy

1 via several different molecular pathologies (degeneracy).

2 degeneracy of the electronic bands (Kramers degeneracy).

3 t react with a variety of different ligands (degeneracy)?

4 nlikely topological because of the near spin degeneracy.

5 turbed system and the resulting quantum near-degeneracy.

6 demonstrates a selective basis for metabolic degeneracy.

7 Protein Data Bank (PDB), finding remarkable degeneracy.

8 in optical lattices, and through accidental degeneracy.

9 erials, inversion symmetry protects the spin degeneracy.

10 isms that possess mammalian-like splice site degeneracy.

11 esting effects occur in systems with orbital degeneracy.

12 r further cooling into the regime of quantum degeneracy.

13 main driving mechanism for the occurrence of degeneracy.

14 gle nucleotides in the DNA target, with some degeneracy.

15 ts can be used to define both complexity and degeneracy.

16 rrents induced by the lifting of spin/valley degeneracy.

17 ed by alloying with MgTe to control the band degeneracy.

18 , and observe that frustration induces extra degeneracy.

19 cold molecular gas prepared close to quantum degeneracy.

20 have this dispersion, giving rise to valley degeneracy.

21 nt with the breaking of the threefold valley degeneracy.

22 f the original tumor mutation (AGG) by codon degeneracy.

23 l properties supporting a degeneracy or near-degeneracy.

24 racy that interconnects 1D lines with double-degeneracy.

25 and systems with significant chemical-shift degeneracy.

26 gas of rubidium-87 ((87)Rb) atoms to quantum degeneracy.

27 ng in bilayers occurs without lifting valley degeneracy.

28 ensity interaction gives rise to topological degeneracy.

29 ixing and, hence, covalency driven by energy degeneracy.

30 stemming from the direct band-gap and valley degeneracy.

31 nt to lift both the spin and the Dirac Cones degeneracies.

32 polaritons which have non-Hermitian spectral degeneracies.

33 erry phase is associated with these spectral degeneracies.

34 bitrarily high-order accuracy away from such degeneracies.

35 mesoscopic system of arbitrary spectrum and degeneracies.

36 ionality of the topologically protected band degeneracies.

37 (PbSe and PbTe) benefit from the high valley degeneracy (12 or more at high temperature) of the valen

38 The high level of degeneracy allows encoding 36 colours with 7 nodes by si

39 State degeneracy also broadens the photoluminescence linewidth

40 Non-Hermitian degeneracies, also known as exceptional points, have rec

41 cold molecules so enticing has made reaching degeneracy an outstanding experimental challenge over th

42 f band gap, carrier effective mass, and band degeneracy and convergence.

43 f the spacer cations result in orientational degeneracy and different formation energies, largely exp

44 ically, it has been known that breaking spin degeneracy and effectively realizing spinless fermions i

45 To limit degeneracy and increase experimental sensitivity, we com

46 ctions essential for signaling, but sequence degeneracy and low binding affinities make them difficul

47 i-RRM domain proteins to assess binding site degeneracy and multifactorial splicing regulation.

48 tions can be employed to break the energetic degeneracy and provide selective transformations.

49 ller distortion that removes the ground term degeneracy and reduces the effects of the first-order sp

50 ture theoretical and experimental studies on degeneracy and robustness.SIGNIFICANCE STATEMENT Neural

51 demonstrate a way to decrease the band-edge degeneracy and single-dot photoluminescence linewidth in

52 We classified AREs according to their degeneracy and their transcriptional involvement.

53 he angles are processed to resolve a twofold degeneracy and to select an overall rotation around the

54 We leverage codon degeneracy and type IIs restriction enzymes to generate

55 The unified model is consistent with the degeneracy and variable neurodisplacement theories of la

56 obscured by mutational robustness, sequence degeneracy, and epistasis.

57 Such peculiar degeneracies are distinct features of non-Hermitian syst

58 As a consequence of degeneracies arising from crystal symmetries, it is poss

59 less chiral charge carriers and the fourfold degeneracy arising from their spin and valley degrees of

60 nteractions but conformational entropies and degeneracies as well.

61 toxicity lead to selection for this apparent degeneracy as it is beneficial to facultative methylotro

62 mechanism are designed to provide a form of degeneracy as protection against injury, disease, or age

63 natural setting to study such non-Hermitian degeneracies, as they feature resonant modes and a gain

64 Binding of cAMP eliminates this degeneracy, as it selectively stabilizes the active conf

65 Aligning band extrema to achieve high band degeneracy, as realized in PbTe, is one of the most effi

66 ate of encapsulated ortho water has a lifted degeneracy, associated with symmetry-breaking of the wat

67 s of fermions arise, differentiated by their degeneracies at and along high-symmetry points, lines, a

68 stal structural blocks in real space or band degeneracy at certain points in reciprocal space.

69 structure correlated well with the level of degeneracy at different peptide positions.

70 ersal or inversion symmetry breaking to lift degeneracy at Dirac points.

71 ments have shown changes in the Landau level degeneracy at fillings corresponding to an integer numbe

72 latter as a result of possessing a high spin-degeneracy at finite low temperatures--making them the v

73 rrelated with local binding of other TFs and degeneracy at key bases in the pioneer factor target mot

74 the magnetic field increases, reaching near degeneracy at nonzero magnetic field.

75 ymmetry, which emerges from the bound states degeneracy at quarter filling.

76 e CoSb3 is typically attributed to threefold degeneracy at the conduction band minimum accompanied by

77 ion spectra and DFT calculations show that a degeneracy at the Gamma point of the energy bands of the

78 These are regions of degeneracy between electronic states on the nuclear land

79 ization, we find that ASR enters a region of degeneracy between the first and second excited states n

80 For these planets, there is a degeneracy between the mass and composition of both the

81 Breaking the degeneracy between these models requires obtaining const

82 presence of a conical intersection (point of degeneracy between two Born-Oppenheimer electronic poten

83 Degeneracy breaking between the [Formula: see text] and

84 mental and specific isotopic labeling reduce degeneracy, but experiments to measure long-range intera

85 iddle of the Sigma line, increasing the band degeneracy by a factor of three.

86 urn has stimulated attempts to engineer such degeneracy by adopting low-dimensional nanostructures.

87 Lifting the valley degeneracy by Zeeman splitting has been demonstrated rec

88 ds of crystalline solids generically exhibit degeneracies called band-structure nodes.

89 ion properties of second-order non-Hermitian degeneracies can provide a means of enhancing the sensit

90 Diabolical points (spectral degeneracies) can naturally occur in spectra of two-dime

91 ical semimetals feature protected nodal band degeneracies characterized by a topological invariant kn

92 ne, although the trend is dependent upon the degeneracy class of the codons.

93 ere we establish mathematical definitions of degeneracy, complexity and robustness that allow for the

94 We use hybrid degeneracy-corrected vibrational perturbation theory to

95 s make up 99.9% of the motifs, the degree of degeneracy correlates negatively with validated transcri

96 along the wavevector Q = (pi, pi, pi), where degeneracy could induce sign-reversal of the pairing sym

97 are has been introduced to annotate spectral degeneracy, current approaches are unable to represent s

98 The first principle, degeneracy, dictates that different neural networks are

99 Use of a replicon library with codon degeneracy did allow identification of second site compe

100 This signal degeneracy diminishes the signal-to-noise ratio, while i

101 ch as regulatory region type, motif sequence degeneracy, DNase accessibility and pairing genomic dist

102 ommonly made when interpreting mass spectral degeneracy do not hold in general.

103 elements to probe and tune effects of energy degeneracy driven covalency.

104 bilayers of MoTe2 without lifting the valley degeneracy, due to spin-valley-layer coupling.

105 pological properties, including ground-state degeneracy, edge physics and anyonic bulk excitations, b

106 rporates an extremely high level of receptor degeneracy, enabling each TCR to recognize multiple pept

107 r the mechanistic bases for this specificity/degeneracy enigma and also compare and contrast Ag recog

108 ld size, but a ground state with topological degeneracy for all system sizes larger than this thresho

109 ich highlights the importance of the orbital degeneracy for many-body states in bilayer graphene.

110 We show that degeneracy has consequences for task switching.

111 However, the extent of such TCR degeneracy has never been fully quantified.

112 Non-Hermitian degeneracies have also been exploited in exotic laser sy

113 While theoretical considerations of degeneracy have been well established in neural networks

114 The existence of spin textures with Kramers degeneracy, however, is difficult to observe directly.

115 e two heptapeptide motifs could exhibit high degeneracy if coded by separate nucleotide sequences, an

116 It is not clear whether network degeneracy impacts network function or is simply a refle

117 nct combination of spin, valley, and orbital degeneracies in bilayer graphene is predicted to produce

118 modifies the structure of modes and spectral degeneracies in exciton-polariton systems, and, therefor

119 rk paves the way for utilizing non-Hermitian degeneracies in fields including photonics, optomechanic

120 observations of the moment of inertia, break degeneracies in gravitational wave detection to measure

121 Degeneracies in physical and biological systems can be l

122 s benefited greatly from previously observed degeneracies in structure.

123 tunity, with future measurements, to resolve degeneracies in the parameters describing the central gr

124 Such degeneracies in the single-particle spectrum strongly en

125 rm mid-gap bound states with spin and valley degeneracies in the vicinity of a Coulomb impurity.

126 mber of 2000 atoms, 1400 atoms reach quantum degeneracy in 300 milliseconds, as confirmed by a bimoda

127 The calculation of degeneracy in a biological network is a useful metric fo

128 Ground-state degeneracy in AgSbTe2 leads to the natural formation of

129 Protocols for attaining quantum degeneracy in atomic gases almost exclusively rely on ev

130 for the phenomena of immunodominance and MHC degeneracy in both types of responses and constrains vac

131 ate a general strategy for achieving quantum degeneracy in dipolar molecular gases in which strong, l

132 Degeneracy in eukaryotic translation initiation is evide

133 It tolerates limited degeneracy in its target sequence, including substitutio

134 Here we outline sources of peak degeneracy in mass spectra that are not annotated by cur

135 lize spinless fermions by splitting the spin degeneracy in momentum space.

136 Breaking the valley degeneracy in monolayer transition metal dichalcogenides

137 ding network of Aplysia and demonstrate that degeneracy in network function can have consequences for

138 Conformational degeneracy in the dendrimers resulted in effective preor

139 ance to overall neuronal activity because of degeneracy in the function of multiple conductances and

140 Degeneracy in the genetic code, which enables a single p

141 xperiment that resolves (15)N chemical shift degeneracy in the indirect dimension.

142 w the first direct evidence of lifted valley degeneracy in the monolayer TMD WS2.

143 Our results reveal extensive degeneracy in the PhoQ-PhoP interface and epistasis, wit

144 tly, however, the use of TALEs is limited by degeneracy in the site-specific manner by which they rec

145 le currents, implying a need for ion channel degeneracy in the tuning of neuronal properties.

146 Lifting the valley degeneracy in these materials is of great interest becau

147 ts have observed the lifting of the fourfold degeneracy in very large applied magnetic fields, separa

148 mponents with overlapping functionality (i.e degeneracy) in organisms.

149 Since the degree of chemical shift degeneracy increases with protein size, the use of 4D NO

150 CSs that can be used to raise conformational degeneracies inherent to different data types, and apply

151 Quantum corrections break the classical degeneracy into a set of aperiodic spin configurations f

152 form within the Landau levels and lift these degeneracies is unclear at present and is a topic of int

153 Hence, level degeneracy is a thermodynamic resource that may effectiv

154 The degeneracy is broken when the molecule is contacted to t

155 Such degeneracy is critical to explain the sensitivity of CBD

156 ately for potential laser applications, this degeneracy is incompletely lifted in the valence band, s

157 ctive Ag, Cu, and Ni, the polymorphic energy degeneracy is lifted and a particular planar structure i

158 ubly degenerate at ambient pressure, but the degeneracy is lifted at high pressures.

159 structure to two excitonic eigenmodes whose degeneracy is lifted by a large approximately 0.71 meV c

160 This degeneracy is lifted within Si quantum wells clad betwee

161 We show that such degeneracy is modulated by the preorganized structure of

162 This degeneracy is paradoxical, as it reduces specificity and

163 es a controllable break in the symmetry, the degeneracy is removed and the two modes couple, exchangi

164 nced when operated at non-Hermitian spectral degeneracies known as exceptional points.

165 that the system possesses a specific type of degeneracy known as an exceptional point.

166 iard exhibit multiple non-Hermitian spectral degeneracies, known as exceptional points.

167 cal systems admit a special kind of spectral degeneracy, known as exceptional point (EP), at which ei

168 nocrystals in solution, including structural degeneracies, lattice parameter deviations, internal def

169 n, valley isospin, and an accidental orbital degeneracy, leading to a complex phase diagram of broken

170 wever, spin-orbit interactions lift the spin degeneracy, leading to a Rashba metal whose Fermi surfac

171 agnetic anisotropy results from this orbital degeneracy, leading to single-ion magnet (SIM) behavior.

172 ideally trigonal Ni(II) complex, the orbital degeneracy leads to a first-order spin-orbit coupling th

173 However, network degeneracy leads to a large number of flux distributions

174 n mass spectrometry-based metabolomics, this degeneracy leads to inflated false discovery rates, data

175 explanation is a local, fluctuating, orbital-degeneracy-lifted state.

176 ur study suggests that organisms can exploit degeneracy lifting as a general strategy to adapt protei

177 NM, like many large proteins, chemical shift degeneracy limits the usefulness of this approach.

178 ly degenerate free-energy landscape and such degeneracy maximally amplifies the response to weak ( ap

179 These results illuminate how genetic code degeneracy may function to specify properties beyond ami

180 Degeneracy means that several different molecular pathol

181 To study whether RE degeneracy might serve a biological function, we develop

182 rsion at zero wave number when an accidental degeneracy occurs between thickness mode longitudinal an

183 Degeneracy occurs when more than one set of parameters p

184 xceptional points (EPs) are special spectral degeneracies of non-Hermitian Hamiltonians that govern t

185 the n-type versions are limited to a valley degeneracy of 4 in the conduction band.

186 n heavy actinide interactions stems from the degeneracy of 5f orbitals with ligand molecular orbitals

187 Here, we derive the average conformational degeneracy of a lattice polypeptide chain in water and q

188 e have revealed the lifting of a vibrational degeneracy of a mode of PDI on Ag(111) and Ag(100) surfa

189 tly observed as a splitting of the four-fold degeneracy of a single electron in ultra-clean quantum d

190 al-gain media are complicated by a non-unity degeneracy of band-edge states, because of which multiex

191 The degeneracy of BEC and interaction between its two compon

192 ic regulator binding, burst-like expression, degeneracy of binding motifs and massive regulatory rewi

193 ed, leading to strong frustration and a near degeneracy of different ground states.Materials with a K

194 Colloidal quantum dots (CQDs) feature a low degeneracy of electronic states at the band edges compar

195 ffect and spin-orbit coupling in lifting the degeneracy of frontier orbitals in highly symmetric thal

196 The degeneracy of interface space is largely due to the pack

197 great interest because lifting the energetic degeneracy of left- and right-handed spin textures in ma

198 Lifting the valley degeneracy of monolayer transition metal dichalcogenides

199 systems and suggest either through the near-degeneracy of nearby electronic phases or direct carrier

200 Due to degeneracy of nucleotide content among binding site inst

201 d two mechanisms that are suited to lift the degeneracy of partially filled electronic states and to

202 The high degeneracy of protein sequences and broad expansion of e

203 Strong spin-orbit coupling lifts the degeneracy of t 2g orbitals in 5d transition-metal syste

204 ic memory T cells, by virtue of the inherent degeneracy of T-cell receptor recognition of peptide:maj

205 This transition maintains the threefold degeneracy of the active orbitals in both competing elec

206 ong the valleytronics parameters such as the degeneracy of the band, intervalley transitions, effecti

207 peptide-binding cleft, despite the apparent degeneracy of the CAL binding motif.

208 This degeneracy of the cell response can be linked to the ini

209 Unfortunately, the orbital (valley) degeneracy of the conduction band of bulk Si makes it di

210 alkoxide groups in a plane, which breaks the degeneracy of the d-orbitals and favors oxidation.

211 The double degeneracy of the Dirac bands is protected by a combinat

212 l (T) symmetries in solids leads to a double degeneracy of the electronic bands (Kramers degeneracy).

213 Finally, we note that the degeneracy of the genetic code allows competing 3' splic

214 The degeneracy of the genetic code allows nucleic acids to e

215 The degeneracy of the genetic code allows protein-coding DNA

216 ction of cognate amino acid supply, lift the degeneracy of the genetic code by splitting codon famili

217 Here we show that the degeneracy of the genetic code is lifted by environmenta

218 ghts into how biological systems exploit the degeneracy of the genetic code to control gene expressio

219 Breaking the degeneracy of the genetic code via sense codon reassignm

220 Owing to the degeneracy of the genetic code, a protein sequence can b

221 Due to the degeneracy of the genetic code, most amino acids can be

222 approaches 1; it effectively side-steps the degeneracy of the genetic code.

223 only in a hexagonal rotor network due to the degeneracy of the ground-state dipole rotational energy

224 Surprisingly, the degeneracy of the H(6) CB (a proposed Weyl node) is lift

225 Coulomb interactions break the degeneracy of the Landau levels and can cause the electr

226 h spin symmetry, leads to a fourfold quartet degeneracy of the Landau levels, observed as peaks in th

227 serine (S) residues in KSKRSRR, despite high degeneracy of the motifs in the absence of co-evolutiona

228 This degeneracy of the NBSs is very intriguing and needs expl

229 et gaps resulting from a strong break in the degeneracy of the p orbitals on the formal nitrenium/oxe

230 magnitude higher, which we attribute to the degeneracy of the positronium states.

231 i-site lead to a progressive increase in the degeneracy of the potential energy landscape of the BiFe

232 Perfect degeneracy of the primary and secondary vibration modes

233 ereby a chiral substituent ((s)Bu) lifts the degeneracy of the resultant salts.

234 The spin degeneracy of the Shockley state breaks down below ~90 K

235 red Jahn-Teller-like as it lifts the orbital degeneracy of the square planar, d(7), Co(II) centers, d

236 ltaneously satisfied, giving rise to a large degeneracy of the system ground state.

237 nterplay between interaction effects and the degeneracy of the system is currently unclear.

238 s that such a distortion lifts the energetic degeneracy of the two valence tautomers, while not affec

239 MoSe(2) and WS(2) were chosen for the near-degeneracy of their conduction-band edges, in order to p

240 ngineering approach to break the biochemical degeneracy of these enzymes.

241 The length and degeneracy of these motifs results in their frequent occ

242 etic phases that further highlights the near-degeneracy of various magnetic states.

243 osely related dynamics without breaking spin degeneracies, opening up applications in materials conta

244 h from experimental noise and high levels of degeneracy or codependency in parameters, is often uncle

245 en only for material properties supporting a degeneracy or near-degeneracy.

246 specially strong in the states of electronic degeneracy or pseudodegeneracy, but they cannot be a pri

247 This transient degeneracy, or flickering electronic resonance among sta

248 The spectral degeneracy originates from a version of Kramers' theorem

249 n cool down below the temperature of quantum degeneracy owing to their long lifetimes.

250 strength is sustained at the singlet-triplet degeneracy point.

251 While the degeneracy points in Weyl semimetals are robust against

252 blockade regime and decreases at the charge degeneracy points, while remaining temperature-independe

253 tron-phonon coupling in the vicinity of band degeneracy points.

254 of the electronic structure and the electron degeneracy pressure is required to capture the measured

255 These stars, which are supported by electron degeneracy pressure, reach densities of 10(7) grams per

256 tral complexity and number of chemical shift degeneracies reduce the number of unambiguous NOE assign

257 unusual class that emerges from the type-II degeneracies residing in the complex space of k.

258 rformance optimization, high electronic-band degeneracy, rich multiscale microstructures, and low lat

259 (or conduction) bands to achieve high valley degeneracy should be a general strategy in the search fo

260 rongly linked with the transformation of the degeneracy space.

261 and characteristics, and for examining mode degeneracy, spatial asymmetry and other effects, which c

262 inibands are 4q times degenerate and all the degeneracies (spin, valley and mini-valley) can be lifte

263 By lifting the degeneracy, spin textures manifest themselves in momentu

264 the spin relaxation time and the sub-lattice degeneracy splitting at zero magnetic field.

265 We discuss possible T2N application in degeneracy studies.

266 ies of this reactive gas and demonstrate how degeneracy suppresses chemical reactions, making a long-

267 by the lesser of the binding energy and the degeneracy temperature of the bosons.

268 and its bilayer counterpart exhibit multiple degeneracies that arise through inherent symmetries.

269 revealed thousands of previously unreported degeneracies that reduced the number of unique analytes

270 A responses along a continuum of specificity/degeneracy that defines the IgA repertoire to gut symbio

271 ly charged quasiparticles and a ground-state degeneracy that grows exponentially as these quasipartic

272 fically, it consists of 0D nexus with triple-degeneracy that interconnects 1D lines with double-degen

273 n electron-electron interactions and quantum degeneracy (the latter is due to spin and valley degrees

274 Despite this degeneracy, the solution space of rate constants almost

275 udies have been devoted to such higher-order degeneracies, their experimental demonstration in the op

276 cooled down below the temperature of quantum degeneracy, they can spontaneously form a coherent state

277 This material combination allows spin degeneracy to be lifted without destroying superconducti

278 and highlights the enormous potential of TCR degeneracy to be the causative factor in autoimmune dise

279 ractions lift the six-fold Landau level (LL) degeneracy to form three valley-polarized quantum Hall s

280 is vein, it is well known that a high valley degeneracy (typically </=6 for known thermoelectrics) in

281 y steering it to an exceptional point (EP)-a degeneracy universally occurring in all open physical sy

282 endent low-lying Landau levels possess lower degeneracy, valley-created localization centers, peculia

283 ssemblies were highly ordered but structural degeneracy was evident in multilayers.

284 overcome the problem of (15)N chemical shift degeneracy we developed a heteronuclear zero-quantum (an

285 On the basis of optical mode degeneracy, we break time-reversal symmetry in different

286 At the onset of quantum degeneracy, we observe the effects of Fermi statistics o

287 s correspond to isolated points of bulk band degeneracy, Weyl nodes, which are connected only through

288 hat redundant components will not yield high degeneracy whereas compensatory mechanisms established b

289 re of a Dirac cone resulting from accidental degeneracy, whereas the complex eigenvalues of the syste

290 ping can drive exciton-polaritons to quantum degeneracy, whereby they form a macroscopically populate

291 ures of 178 proteases highlights proteolytic degeneracy wired into the SARS-CoV-2 lifecycle.

292 udied their properties, including their near degeneracy with bright excitons and their formation path

293 By combining degeneracy with optimal primer reuse the user may increa

294 the soft interlayer excitations and the near-degeneracy with other smectic phases.

295 d intrinsic phase response, and suggest that degeneracy with reference to several coexisting function

296 ersurfaces in the reaction, and an S(0)-T(1) degeneracy with SOC for the critical diradical.

297 with a significant increase in An 5f energy degeneracy with the dipicolinate molecular orbitals for

298 n used; however, there is an issue regarding degeneracy with these properties, as native and nonnativ

299 identified, including solids with high band degeneracy, with cages in which atoms rattle, with nanos

300 It shows an exotic configuration of degeneracies without a well-defined dimensionality.