ライフサイエンスコーパス: mesophase

1 lline phase Lc melts back to the equilibrium mesophase).

2 s uses a spontaneously forming lipidic cubic mesophase.

3 ctions and the ordering of the solute in the mesophase.

4 material exhibits a previously unidentified mesophase.

5 and the spatial dimensions of the resulting mesophase.

6 thermal annealing in the liquid crystalline mesophase.

7 acceptor columns within each of the observed mesophases.

8 ity to self-assemble into liquid crystalline mesophases.

9 al (space group p6mm) silica-block copolymer mesophases.

10 bility of the nematic and twist-bend nematic mesophases.

11 ems exhibit both chiral nematic and columnar mesophases.

12 in the nematic, chiral-nematic, and smectic mesophases.

13 allization of membrane proteins from lipidic mesophases.

14 stallization of membrane proteins in lipidic mesophases.

15 or into the nematic, cholesteric and smectic mesophases.

16 , and alignment features inherent in nematic mesophases.

17 oardlike materials that display only nematic mesophases.

18 een the lamellar and columnar (2D hexagonal) mesophases.

19 ergent and/or lipids that often form various mesophases.

20 phide were prepared from inverse cubic lipid mesophases.

21 tallogenesis of membrane proteins in lipidic mesophases.

22 The various kinds of chiral mesophases able to reveal enantiotopic discrimination in

23 confirmed the formation of a stable nematic mesophase above 37.5 degrees C for NPs in the 6-11 nm si

24 l twist-bend phase into a lamellar smectic A mesophase, additionally this material exhibits a previou

25 The bundle stoichiometry in the mesophase agrees well with the size found in solution fo

26 s of ionic volumes with the occurrence of LC mesophase and its stability are revealed, thus paving th

27 membrane protein crystallization in lipidic mesophases and for studies of the suitability of precipi

28 Sufficient levels of lipids forming lamellar mesophases and lipids forming hexagonal I mesophases, wh

29 ated assembly of carbon nanotubes using soft mesophases and the development of functional nanocomposi

30 xyldecyl) disfavor the formation of lamellar mesophases and, instead, induce higher ordered soft crys

31 organized morphology from processing in the mesophase, and the effects of exposure to both ambient a

32 imal background due to the surrounding lipid mesophase ( approximately 1 thousand counts/s).

33 Nematic mesophases are much less commonly observed in discotic s

34 eir supramolecular organizations within both mesophases are proposed.

35 heir nonplanarity, the aromatic cores in the mesophases are tightly stacked within the column.

36 )H 1D/2D-NMR in chiral polypeptide lyotropic mesophases, are presented and analyzed.

37 the mechanism of crystallization in lipidic mesophases as discussed.

38 mplating, which use amphiphilic or colloidal mesophases as templates for inorganic mesoporous materia

39 xagonally ordered polyelectrolyte-surfactant mesophase based on the electrostatically induced co-asse

40 udies of the suitability of precipitants for mesophase-based crystallization methods.

41 on of a cubic Ia3d chitosan-ruthenium-silica mesophase before pyrolysis and silica removal.

42 id molecular structure and liquid crystal or mesophase behavior be established.

43 at dynamical disorder is crucial in defining mesophase behaviour, and that the apparent kinetic barri

44 osol-OT (AOT)/water mixtures in the lamellar mesophase, bicontinuous cubic (BC) phase, and in an anal

45 d via a phase transformation from a lamellar mesophase by hydrothermal reaction in the presence of an

46 0 instead directs the assembly into lamellar mesophases by increasing the proportion of pi-conjugated

47 We then probe the transitions between mesophases by varying the PEG solution osmotic pressure,

48 in concentration in the bilayer of the cubic mesophase can be ramped up stepwise from less than a mil

49 w the molecular organization inherent to the mesophase can control the polarization of light-emitting

50 w the molecular organization inherent to the mesophase can control the polarization of light-emitting

51 and proton gradients, we show that the doped mesophase can operate as a charge separation device rely

52 ons in polyelectrolyte-azobenzene surfactant mesophases can be exploited for photo-induced long-range

53 sophase formation, and the potential to tune mesophase characteristics via manipulation of these fact

54 LCP is a liquid-crystalline mesophase composed of lipids and water.

55 Self-assembled lamellar silica-surfactant mesophase composites have been prepared with crystal-lik

56 The mesophase comprises gold nanocrystals arranged within a

57 higher temperature to a surfactant-boehmite mesophase, denoted MSU-S/B, with a lathlike framework ma

58 ow) was observed upon crystallization of the mesophase due to a phase separation of the component don

59 NC micelles into ordered NC/silica thin-film mesophases during spin coating.

60 roperties depend crucially on the particular mesophase employed.

61 ive membrane protein transporters in lipidic mesophases, exemplified by the bacterial ClC exchanger f

62 sors, ion channels, self-healable materials, mesophases for the controlled release of bioactive compo

63 The dramatic effect on mesophase formation and stability engendered via donor-a

64 terms of the interplay of forces leading to mesophase formation, and the potential to tune mesophase

65 tational symmetry is in general conducive to mesophase formation, with low anisotropy favouring plast

66 lipid classes present and hence, the type of mesophase formed, is essential.

67 The interactions between mesophase-forming copolymers and nanoscopic particles ca

68 ructures could be best understood by using a mesophase framework of a binary mixture of lipids and pe

69 molecular organization in the self-assembled mesophases from structures with initially amorphous sili

70 This new mesophase, h-C(18)PyReSeBr, exhibits remarkably well ord

71 silicate framework in a surfactant-templated mesophase has been established by using a combination of

72 Lipid based lyotropic liquid crystalline mesophases have demonstrated exceptional responsiveness

73 hydration, phospholipid chemical structure, mesophase identity, aqueous medium composition, and inci

74 crystals (ILs that adopt liquid crystalline mesophases, ILCs) for predicting the domain of their exi

75 We report that annealing from the mesophase improves the order and packing of organic semi

76 We report that annealing from the mesophase improves the order and packing of organic semi

77 characterize the columnar liquid-crystalline mesophases in concentrated solutions of various model G-

78 terials form thermotropic columnar hexagonal mesophases in which the peptides adopt an alpha-helical

79 Analysis of these mesophases indicates mixtures with soft/plastic crystal

80 terlamellar space of a reverse microemulsion mesophase into stacks of nanosheets interleaved with cet

81 ture, lipid bilayer properties and the lipid mesophase is limited.

82 , the interaction between tryptophan and the mesophase is very slight as revealed by its low partitio

83 ctions and the pitch of the resulting chiral mesophases is lacking.

84 agen structures form from liquid crystalline mesophases is not well characterized.

85 nanostructured lyotropic liquid crystalline mesophases may form in select mixtures of amphiphile and

86 ipid bilayers through the use of the lipidic mesophase method, and determined its structure at 3.5 A

87 action was used for phase identification and mesophase microstructure characterization.

88 about how transport properties of the doped mesophase mirror the original molecular gating features

89 e clearing and crystallization points of the mesophase mixtures and the melting/clearing points of th

90 s study, we evaluate its effect on the cubic mesophase of hydrated monoolein.

91 The self-assembled mesophase of zirconium phosphate nanoplatelets is stabil

92 d (b) inducing vertically oriented hexagonal mesophases of micelle-silica composite.

93 ding shear-induced phenomena in concentrated mesophases of mixed amphiphilic systems.

94 SAXS), we investigated the phase behavior of mesophases of monoolein (MO) mixed with additives common

95 crowding conditions, with the corresponding mesophases of the canonical duplex and triplex DNA analo

96 tant, we varied the resulting self-assembled mesophases of the composite material.

97 Finally, we compare the mesophases of the G-quadruplexes, under PEG-induced crow

98 re this vast parameter space and predict the mesophases of the hybrids, we have developed a mean fiel

99 The columnar mesophases of two series of hexacatenar palladium(II) me

100 nematic, hexagonal, and rectangular columnar mesophases over a considerably wide temperature range, i

101 a two-dimensional (2-D) hexagonal thin-film mesophase (p6mm) with cylinder axes oriented parallel to

102 espondence enables the predictable tuning of mesophase phase transition temperatures.

103 characteristics of CIM carbon prepared from mesophase pitch lead to outstanding performance of these

104 thiolates into an ordered liquid crystalline mesophase plays an essential role in templating the disk

105 tution of membrane proteins in lipidic cubic mesophases plays a prominent role in membrane protein cr

106 tution of membrane proteins in lipidic cubic mesophases presents significant challenges related to th

107 n disordered (H1) or liquid crystalline (T1) mesophases require additive processing to promote crysta

108 Most materials show mesophases stable to high temperatures.

109 ields of surfactant and multiblock-copolymer mesophases, still remains a mesostructure that has not b

110 ort amphiphile self-assembly into a range of mesophase structures has been established as a widesprea

111 s the order parameter of the system within a mesophase sufficiently.

112 Absence of physical distortion of the mesophase suggests that the SWNTs are stabilized by adso

113 he presence of molecular porogens, lyotropic mesophases, supramolecular architectures, emulsions, org

114 n was realized, resulting in a protein-laden mesophase that allowed the formation of crystals using t

115 Hydrated monoolein forms the cubic-Pn3m mesophase that has been used for in meso crystallization

116 A variety of 1:1 Dan:Ndi mixtures produced mesophases that were found to be stable over temperature

117 ate surface forms from an incipient lamellar mesophase through a correlated micellar intermediate.

118 port the synthesis of a new nanocrystal (NC) mesophase through self-assembly of water-soluble NC mice

119 emically converts the intermediate boehmitic mesophase to a mesostructure with crystalline gamma-Al(2

120 edia, reaction-diffusion systems and coupled mesophases to produce higher-level hybrid structures und

121 tting behavior; and for optically defining a mesophase transformation (from hexagonal to tetragonal)

122 the apparent kinetic barrier for the liquid-mesophase transition is much lower for liquid crystals (

123 Additionally, cyclo[6]aramides show unusual mesophase transitions from lamellar to hexagonal columna

124 stability of both the nematic and twist-bend mesophases upon this angle, thereby satisfying earlier t

125 lume fractions, the formation of a hexagonal mesophase was observed.

126 compartmentalized within a silica-surfactant mesophase were prepared by an evaporation-induced self-a

127 on the lattice parameters of fully hydrated mesophases were found between ternary and quaternary mix

128 Depending on the molecular structure, two mesophases were observed: a bilayered SmA2 phase and the

129 Lyotropic mesophases, where membranes conform to periodic minimal

130 SWNTs are incorporated into a surfactant mesophase which forms 2.3 nm diameter water channels by

131 ar mesophases and lipids forming hexagonal I mesophases, which respectively form condensed monolayers

132 ance demonstrate that DOBMP forms a lamellar mesophase with acyl-chain packing similar to that of oth

133 1.52 x 10(-)(3) cm(2) V(-)(1) s(-)(1) in the mesophase with an activation energy of 0.06 +/- 0.01 eV.

134 n be polymerized in both the H(I) and a Q(I) mesophase with retention of phase microstructure.

135 leads to the formation of highly segregated mesophases with a complex multilayered structure due to

136 kly swollen isotropic (Li) and lamellar (La) mesophases with bilayers formed in a cationic-anionic mi

137 id crystals with chiral constituents exhibit mesophases with modulated ground states.

138 ls are open framework chalcogenides and form mesophases with uniform pore size (with spacings between

139 For the optimum donor-acceptor organized mesophases within this grid, temperature stability range