ライフサイエンスコーパス: Ostwald

1 Ostwald ripening allows the synthesis of 1D nanorods of

2 Ostwald ripening and intraparticle ripening were stopped

3 Ostwald ripening processes are visualized simultaneously

4 n and coalescence of liquid domains, and 2), Ostwald ripening.

5 recritical nucleus sizes, apparently against Ostwald's step rule.

6 heterogenous recrystallization via aggrading Ostwald ripening with interfingering reaction fronts typ

7 A century ago Ostwald described the "Rule of Stages" after deducing th

8 unusual phenomena have been thought of as an Ostwald ripening process that is driven by the capillari

9 -quality MAPbI3-xBrx thin films following an Ostwald ripening process, which is strongly affected by

10 llization of the MOF was found to undergo an Ostwald ripening process, during which the defects also

11 models such as Smoluchowski coalescence and Ostwald ripening.

12 ion processes (i.e., nucleation, growth, and Ostwald ripening) were modulated by sulfate.

13 Our results support a two-step process and Ostwald's rule of stages for the crystallization of hete

14 the liquid phase, the Bergeron process, and Ostwald ripening.

15 e interactions impede complete reduction and Ostwald ripening of nickel species into the less hydroge

16 oil phase at variable proportions (0-60%) as Ostwald ripening inhibitor and viscosity modifier.

17 en well described by various models, such as Ostwald ripening and coalescence.

18 while those nearby in the matrix coarsen by Ostwald ripening due to the increased atomic mobility.

19 follows classical growth kinetics driven by Ostwald ripening (i.e., growth of large clusters at the

20 h vapour-liquid-solid mechanism, followed by Ostwald ripening to form the jellyfish-like morphology.

21 ticle formation is predominantly governed by Ostwald ripening processes.

22 to be invariant as the nanodroplets grow by Ostwald ripening and also with substitution of different

23 rature allows for further particle growth by Ostwald ripening.

24 olecularly imprinted silica nanoparticles by Ostwald ripening in the presence of molecular templates

25 mediate reaction conditions, as predicted by Ostwald.

26 cess is multi-step in nature and proceeds by Ostwald's step rule through which coalescence of soluble

27 i.e., generally, small NCs sinter rapidly by Ostwald ripening, while larger NCs sinter slowly by crys

28 particles grow by coalescence rather than by Ostwald ripening.

29 ped CO(2) in the pore space, which is called Ostwald ripening.

30 ain-addition of monomers to stable clusters (Ostwald ripening) in the presence of excess phosphinic o

31 It is found that colloidal Ostwald ripening, metal reactivity, and deposition amoun

32 like to platelet crystals that defies common Ostwald ripening processes.

33 It contradicts Ostwald's law of stages and other theories of crystalliz

34 results provide a novel strategy to control Ostwald ripening and maintain the high antibacterial act

35 ppear to be formed by a diffusion-controlled Ostwald-ripening growth mechanism.

36 2 nanoparticles occurs via both conventional Ostwald ripening and nonclassical crystallization by par

37 evolve in a way similar to the conventional Ostwald ripening, during which larger droplets grow at t

38 rownian coalescence and, to a lesser degree, Ostwald ripening.

39 ve and study NP coarsening and differentiate Ostwald ripening from coalescence processes.

40 This leads to the well-documented Ostwald ripening.

41 galvanic replacement, the Kirkendall effect, Ostwald ripening, dissolution-regrowth, and the surface-

42 iation energies (in lieu of surface energy), Ostwald ripening is not suppressed, despite the size-sel

43 d Au(923+/-20) clusters are found to exhibit Ostwald ripening, whereas Au(2057+/-45) ripens through c

44 In contrast to an expected Ostwald-like ripening of amyloid assemblies, the nucleat

45 odynamically favorable nanofibrils following Ostwald's step rule.

46 y, and enhanced connectivity, resulting from Ostwald ripening.

47 p crystallization governed by the heuristic "Ostwald's rule of stages", which predicts that the cryst

48 s the interface, originating two independent Ostwald ripening processes, which drive the high aspect

49 e, it can be applied to successfully inhibit Ostwald ripening in a multitude of foam and emulsion app

50 urface of smaller CaCO(3) nuclei, inhibiting Ostwald ripening.

51 s is lowered by coarsening which can involve Ostwald ripening or Smoluchowski ripening (NC diffusion

52 ch is markedly different from the well-known Ostwald ripening process with [Formula: see text].

53 nucleation theory, and empirical rules, like Ostwald's rule, should be modified to account for the ro

54 vations are largely consistent with modified Ostwald ripening processes.

55 mes of the CdSe nanocrystals with negligible Ostwald ripening, while retaining the crystallographic p

56 PPEs obtained showed neither coalescence nor Ostwald ripening, as reflected by emulsion index and dro

57 en 80 and 5 wt% oil phase comprising 30 % of Ostwald ripening inhibitor and 70 % of HEO.

58 ng, hydrolysis, or those taking advantage of Ostwald ripening and the Kirkendall effect, are reviewed

59 zation pathways extends the applicability of Ostwald's step rule to interfacial atom states, and enab

60 that measurements that ignore the effect of Ostwald ripening overestimate the residual saturation by

61 Evidence of Ostwald's ripening was also observed under these experim

62 rmediate state, the first direct evidence of Ostwald's rule of stages at 2D.

63 to equilibrate, in a novel manifestation of Ostwald's rule of stages.

64 rm this result and reveal a manifestation of Ostwald's step rule, where the strong metastability of g

65 utions, explaining the microscopic origin of Ostwald's step rule.

66 to occur only outside droplets, the rate of Ostwald ripening can be increased by an arbitrarily larg

67 Here we report the role of Ostwald's Rule of Stages in the growth of CdSe quantum d

68 provide evidence supporting the ubiquity of Ostwald's Rule of Stages, describing the hypothesized tr

69 rom the smaller droplets to the larger ones (Ostwald ripening) leads to nanowire diameters that chang

70 Coarsening or Ostwald ripening occurs in a vast array of two-phase sys

71 ial transport through interfacial contact or Ostwald ripening at super-saturating conditions and was

72 The spheres develop via an inside-out Ostwald ripening mechanism.

73 tions of a transition from normal to reverse Ostwald ripening for self-rotating odd grains, and a tra

74 This MABr-selective Ostwald ripening process improves cell efficiency but al

75 Size selection was demonstrated to suppress Ostwald ripening of supported catalytic nanoparticles.

76 are introduced after nucleation to suppress Ostwald ripening, meanwhile, ammonium hexafluorophosphat

77 We argue that Ostwald's rule also holds for the aggregation of fused i

78 Analysis of the growth curves shows that Ostwald ripening only takes place above 200 degrees C, a

79 The Ostwald ripening is not activated by thermal annealing o

80 The Ostwald rule of stages describes the conjectured transit

81 The Ostwald step rule, based on a thermodynamic view of nucl

82 een NPs and substrate, thus slowing down the Ostwald ripening process during post-oxidative calcinati

83 have limited applicability for modeling the Ostwald process.

84 e explain why established rate models of the Ostwald process incorrectly predict low selectivity and

85 d size, perhaps due to the inhibition of the Ostwald ripening process.

86 Direct observation of the Ostwald rule of stages using was performed using solutio

87 he remarkable ability to completely stop the Ostwald ripening commonly associated with nanoemulsions.

88 thus inducing orientated growth through the Ostwald ripening process by phagocytizing unstable nanoc

89 transformations that is consistent with the Ostwald rule of stages, wherein metastable structures di

90 sm forcing ATPS formation to proceed through Ostwald ripening.

91 er, round colonies, and a phenomenon akin to Ostwald ripening - a coarsening process seen in many sys

92 This was attributed to Ostwald ripening in which the small nanoparticles dissol

93 Droplet growth was attributed to Ostwald ripening, i.e., diffusion of lemon oil molecules

94 ased in size after dissolution likely due to Ostwald ripening.

95 that contain multiple crystallites leads to Ostwald ripening and annealing of the ice structures, ac

96 and growth kinetics (including resistance to Ostwald ripening), this procedure allows for in situ gro

97 rease in heat capacity), and is resistant to Ostwald ripening.

98 presumed lipid flip-flop process similar to Ostwald ripening, the smaller domains in one leaflet ero

99 ervation of a crossover from Smoluchowski to Ostwald ripening, under realistic reaction conditions, f

100 he tendency of lead chalcogenide NQDs toward Ostwald ripening at even moderate reaction temperatures.

101 propensity of oxidized Pt species to undergo Ostwald ripening phenomena because of the physical barri

102 queous solutions are key clues to understand Ostwald's step rule.

103 mously emerge from a previously unrecognized Ostwald ripening mechanism and they capture rich informa

104 verting NaYF(4) nanocrystals (NCs) utilizing Ostwald ripening dynamics tunable both in thickness and

105 This study validates Ostwald's Rule of Stages and provides a phase diagram fo

106 tion of the precursor supply drives vertical Ostwald ripening, which prevents secondary nucleation de

107 ayer-by-layer growth of a platinum shell via Ostwald ripening during the oxygen annealing treatment.

108 tals through mesoscale transformation, where Ostwald ripening is responsible for the growth of the na

109 o the different N* states are in accord with Ostwald's rule of stages, with the least stable structur

110 the S-bend topology, which is in accord with Ostwald's rule rationalizing crystal polymorph formation

111 cursor to crystallization in accordance with Ostwald's step rule of phases.

112 transformations of ZIFs are consistent with Ostwald's rule of stages and proceed toward thermodynami

113 conclusion is that the changes fit well with Ostwald's Law of Stages with the orthorhombic form alway