ライフサイエンスコーパス: coarsening

1 lved in foaming, emulsification, and droplet coarsening.

2 lacements-per-atom (dpa) with moderate grain coarsening.

3 n of the AgNPs and inhibited aggregation and coarsening.

4 to 3 also promoted particle aggregation and coarsening.

5 subnetwork that may be utilized for further coarsening.

6 ium, representing a new approach to directed coarsening.

7 fail to reproduce temporally correct network coarsening.

8 s of modern theories of diffusion-controlled coarsening.

9 h, the actin cytoskeleton showed only subtle coarsening.

10 in situ TEM to directly observe and study NP coarsening and differentiate Ostwald ripening from coale

11 and provide a possible mechanism for domain coarsening and eventual molecular alignment in monolayer

12 The twin coarsening and heterogeneous recrystallization resulted

13 but their utility as catalysts is limited by coarsening at high temperatures.

14 oskeletal actin networks exhibit significant coarsening, attendant with decreasing average mechanical

15 leads to differences in both morphology and coarsening behavior of the nanoparticles that we used to

16 the number of metal atoms that can engage in coarsening can be controlled with this technique, and TE

17 f these topologically complex systems during coarsening can be quantified by measuring the probabilit

18 t-order phase transition in which late-stage coarsening dynamics are mediated by Brownian coalescence

19 phenomena are always strongly implicated in coarsening dynamics but are, in detailed-balance systems

20 t this additional term has modest effects on coarsening dynamics, but alters the static phase diagram

21 ng on the type of barite used, an additional coarsening effect or a strong formation of oriented aggr

22 e depletion interactions dominate the system coarsening; elastic interactions no longer prevail.

23 the distinctive association of progressively coarsening facial features, relative macrocephaly, and t

24 n, which is associated with anisotropic twin coarsening, heterogeneous recrystallization, and high st

25 dentify the mechanism behind Pt nanoparticle coarsening in an aqueous environment.

26 Data on coarsening in Ni-Al alloys is examined.

27 e of 1,8-diiodooctane and the rate of domain coarsening in the plasticized film which helps elucidate

28 d then progress within seconds to late stage coarsening in which domains grow via two mechanisms 1),

29 Coarsening is a ubiquitous phenomenon that underpins cou

30 This coarsening is even more pronounced when both reactants a

31 Coarsening is markedly curtailed, and the jammed colloid

32 Here, a new model of coarsening is presented, involving diffusive transport t

33 Here we show that the coarsening kinetics of NiAl-type precipitates is in exce

34 n-oxidizing bacteria revealed an alternative coarsening mechanism in which adjacent 2- to 3-nanometer

35 ese results are consistent with an anomalous coarsening model for island growth.

36 results of the present study reconcile with coarsening models from the Lifshitz-Slyozov-Wagner theor

37 ction dependence during diffusion-controlled coarsening of a polydisperse assembly of particles have

38 omic force microscopy (TM-AFM) can drive the coarsening of Au nanoparticle assemblies on silicon surf

39 will strongly influence the condensation and coarsening of drops on soft polymer films, and has poten

40 daughter cracks in striking analogy with the coarsening of finger patterns observed in nonequilibrium

41 and the strong volume-fraction dependence of coarsening of gamma precipitates in an ordered gamma' ma

42 The coarsening of Li2 O2 nanoparticles occurs via both conve

43 enabled to develop raft microdomains through coarsening of nanorafts.

44 d absence of an effect of volume fraction on coarsening of ordered gamma' (Ni3Al) precipitates in a d

45 Fyn deletion resulted in coarsening of podocyte foot processes and marked attenua

46 support the long-standing debate that if the coarsening of Ptnano from crystal migration and coalesce

47 Thus, despite coarsening of the actin cytoskeleton and depressed ATP l

48 The growth and coarsening of the eta' precipitates caused rapid depleti

49 her tissues, including lymphoid hyperplasia, coarsening of the facies, and increased body fat.

50 moval of the surface hydration layers causes coarsening of the nanoparticles.

51 s of two stages: (I) nucleation, growth, and coarsening of the particles to yield a single particle i

52 s from 7.2% to above 8.7% as a result of the coarsening of the phase domains.

53 This limit is set by the onset of the rapid coarsening of the precipitates and consequent loss of me

54 Coarsening of these local features is energetically cost

55 Coarsening or Ostwald ripening occurs in a vast array of

56 cancies between ribbons of endothelial cells coarsening over time.

57 In the presence of coarsening, performing a sensitivity analysis over a ran

58 Much is known about the coarsening process in two-phase mixtures consisting of a

59 This coarsening process is assisted by thermal annealing and

60 nto a global contractile state via an active coarsening process, in contrast to the flow transition d

61 this curvature space that is induced by the coarsening process.

62 o observe intermediate structures as part of coarsening processes that lead to the formation of singl

63 Self climb significantly influences the coarsening rate of defect networks, with important impli

64 l, and applicable to many systems undergoing coarsening, regardless of their topology.

65 precipitates that has enabled us to develop coarsening resistant high-temperature alloys that are st

66 wavelength regions, growing the structure by coarsening, resulting in a broad distribution of domain

67 Coarsening results in a decrease in the interfacial area

68 sliding and rotation and by inhibiting grain coarsening, under extremely long-term creep conditions.