ライフサイエンスコーパス: face-centered

1 l colloids that typically crystallize into a face-centered ABC layer packing.

2 Under the optimal conditions obtained by a face-centered central composite design (FCCD), the PMT-b

3 A face-centered central composite response surface methodo

4 The face centered cubic (fcc) alloy NiCoCrx with x approxima

5 alysis leads to asymptotic states resembling face centered cubic (FCC) and hexagonal close packed (HC

6 Electrodeposited Pt and CuO exhibited face centered cubic (fcc) and monoclinic crystal structu

7 e cubic (SC), body centered cubic (BCC), and face centered cubic (FCC) crystal structures and show th

8 Chemically disordered face centered cubic (fcc) FePt nanoparticles (NPs) show

9 Recent successes in forming different shaped face centered cubic (fcc) metal nanostructures has enabl

10 ften adopt the body centered cubic (bcc) and face centered cubic (fcc) structures.

11 he bead surface expressing a complete set of face centered cubic (fcc) surface structures represented

12 sition from cubic solid solution [denoted as face centered cubic (fcc)] structure to tetragonal inter

13 the six <100> preferred growth directions in face centered cubic alloys.

14 mmetry, which reduces the frustration of the face centered cubic lattice of Os(VI) ions.

15 ly 1 J/m(2), which is expected for bulk fcc (face centered cubic) silver.

16 s are atypical for PBAs, which are typically face centered cubic.

17 s are atypical for PBAs, which are typically face centered cubic.

18 aller grain size, and optimized fractions of face-centered cubic (f.c.c., gamma) and hexagonal close-

19 composed of a hydrogel polymerized around a face-centered cubic (fcc) array of monodisperse, highly

20 iolate ligands and one sulfido ligand with a face-centered cubic (FCC) Au22 kernel.

21 e nC60-stir was a superstructure composed of face-centered cubic (fcc) close-packing of near-spherica

22 ination of the phonon dispersion curves in a face-centered cubic (fcc) delta-plutonium-0.6 weight % g

23 Unlike the previously synthesized disordered face-centered cubic (fcc) FePt nanoparticles with diamet

24 ns of icosahedral (Ih), decahedral (Dh), and face-centered cubic (fcc) isomers within a set of popula

25 Face-centered cubic (fcc) lattice is the only known crys

26 g, which is the Delaunay tessellation of the face-centered cubic (fcc) lattice, and its closely relat

27 med the nature of single supercrystal with a face-centered cubic (fcc) lattice.

28 into superlattice (SL) allotropes of either face-centered cubic (fcc) or body-centered cubic (bcc) s

29 local atomic structure is consistent with a face-centered cubic (fcc) or Marks decahedral arrangemen

30 izes in the space group R3 and adopts pseudo face-centered cubic (fcc) packing, whereas other MOSCs,

31 ing between hexagonal close-packed (hcp) and face-centered cubic (fcc) sites, was seen when the tip w

32 Among these, equatomic CrMnFeCoNi with the face-centered cubic (FCC) structure is noteworthy becaus

33 re transformation from chemically disordered face-centered cubic (fcc) structure to chemically ordere

34 ple, LaH10 is found to adopt a sodalite-like face-centered cubic (fcc) structure, stable above 200 GP

35 Gold is well known to adopt face-centered cubic (fcc) structure.

36 NCs with dense ligand coverage assemble into face-centered cubic (fcc) superlattices whereas NCs with

37 It is face-centered cubic (fcc) to low temperatures with Na(+)

38 of this hypothesis requires the synthesis of face-centered cubic (fcc) trivalent fulleride anion salt

39 c (bcc), body-centered tetragonal (bct), and face-centered cubic (fcc)--as confirmed by synchrotron s

40 The actual ground state is face-centered cubic (fcc).

41 = 1,4,8,11-tetraazacyclotetradecane) afford face-centered cubic [(Me(3)tacn)(8)Mo(8)Ni(6)(CN)(24)](1

42 free from disorder, unlike the well-studied face-centered cubic A3C60 alkali metal fulleride superco

43 nontrivial behavior due to the existence of face-centered cubic and body-centered cubic crystal stru

44 NpN(2) crystallizes in a face-centered cubic CaF(2)-type structure with a space g

45 The data were consistent with a face-centered cubic crystal having a unit crystal cell s

46 Twin nucleation in a face-centered cubic crystal is believed to be accomplish

47 n form with the approximate periodicity of a face-centered cubic crystal, as the spontaneous product

48 The identification of new face-centered cubic crystallographic structure of Ru nan

49 k waves in three-dimensional 10-million atom face-centered cubic crystals with cross-sectional dimens

50 Our predicted spectrum for the face-centered cubic delta phase agrees well with experim

51 s a ligand-deficient layered analogue of the face-centered cubic fcu UiO-67(Hf).

52 ca synthesized under typical conditions is a face-centered cubic Fm3m structure with 3-dimensional he

53 ects that connect this layer to the adjacent face-centered cubic grains, we explain the geometric ori

54 preferably interact with vacant sites of the face-centered cubic lattice above the metal surface.

55 s, it has only recently been proved that the face-centered cubic lattice has the highest possible pac

56 cies that move freely in three dimensions, a face-centered cubic lattice is best.

57 hedral structure, which is a fragment of the face-centered cubic lattice of bulk gold with a small st

58 rystals arranged within a silica matrix in a face-centered cubic lattice with cell dimensions that ar

59 of the four possible 111 glide planes in the face-centered cubic lattice, begins with junction format

60 del or backbone model on either the cubic or face-centered cubic lattice.

61 nd the X-ray structure is best-fitted onto a face-centered cubic lattice.

62 Iridium is unique among the face-centered cubic metals in that it undergoes brittle

63 The (643) and (six four three) planes of face-centered cubic metals such as Cu have kinked and st

64 These observations in two dissimilar face-centered cubic metals suggest that strain recovery

65 winning should thus be highly unfavorable in face-centered cubic metals with high twin-fault energy b

66 e evolution of plasticity in heavily twinned face-centered cubic metals, with the potential for optim

67 cubic nanometer) tetradecahedral cavities in face-centered cubic metals.

68 tetrahedra (SFTs) are ubiquitous defects in face-centered cubic metals.

69 At further compressions and in face-centered cubic Na above 64 GPa, the linear relation

70 In some oblate plasmas, a mixture of bcc and face-centered cubic ordering was seen.

71 Although pristine C60 prefers to adopt a face-centered cubic packing arrangement in the solid sta

72 ody-centered cubic phase, differing from the face-centered cubic phase of both bulk solid xenon and s

73 ticle structure from a chemically disordered face-centered cubic phase to the chemically ordered face

74 However, stable non-face-centered cubic phases have not been reported in nob

75 l lattice may induce distortions to form non-face-centered cubic phases when the lateral dimensions o

76 lloy, CrMnFeCoNi, which forms a single-phase face-centered cubic solid solution, and found it to have

77 ent method, we show that the icosahedron and face-centered cubic SRO increase upon cooling.

78 entered cubic structure to 52 GPa and in the face-centered cubic structure from 64 to 97 GPa, and stu

79 to form crystalline silver nanoparticles of face-centered cubic structure with a mean size of 10 nm.

80 eas along the nanowire axis, with a textured face-centered cubic structure.

81 or proton-irradiated structural metals with face-centered cubic structures.

82 ess, of planar-extended core dislocations in face-centered cubic structures.

83 d a strong tendency to form multiply twinned face-centered cubic superlattices with decahedral and ic

84 chanisms of room temperature rolling induced face-centered cubic titanium (fcc-Ti) in polycrystalline

85 ystal exhibits a phase transformation from a face-centered cubic to a body-centered tetragonal struct

86 pted non-close-packed structures (e.g., from face-centered cubic to body-centered cubic) and changed

87 faults that change the local structure from face-centered cubic to hexagonal close packed.

88 e crystals, whereby a body-centered cubic to face-centered cubic transformation is found to proceed s

89 toms per primitive unit cell (1140 atoms per face-centered cubic unit cell).

90 aining a truncated octahedral core with bulk face-centered cubic-like arrangement, yet a nanomolecule

91 ty in bulk nanolayered composites of a model face-centered-cubic (Cu)/body-centered-cubic (Nb) system

92 S NCs in toluene self-assemble into a single face-centered-cubic (fcc) and body-centered-cubic (bcc)

93 depletion of dislocations from submicrometer face-centered-cubic (FCC) pillars provides a plausible e

94 iously reported body-centered cubic (BCC) or face-centered-cubic (FCC) types, the major structure was

95 dynamics simulations, to elucidate a twinned face-centered-cubic alloy in an experiment with hardness

96 on from an ordered monoclinic structure to a face-centered-cubic arrangement of orientationally disor

97 s this fundamental question by examining the face-centered-cubic Cu-Zn alpha-brasses.

98 lloy transformed upon hydrogenation into the face-centered-cubic fluorite Mg1-yTiyHx phase with favor

99 large as ~30%, at the same level of ductile face-centered-cubic metals.

100 S(*)R or involves direct binding of RS(*) to face-centered-cubic or hexagonal-close-packed sites.

101 few than three atoms energetically prefers a face-centered-cubic stacking, to serve as a nucleus of s

102 toric stress drives SC(110) orientation in a face-centered-cubic supercrystal (SC), rocksalt (RS) NPs

103 6)(SR)(24) nanocluster reveals an unexpected face-centered-cubic tetrahedral Au(28) kernel (magenta).

104 iates on two different facets of these eight face-centered-cubic transition metals, combined with a s

105 A central composite face centered design was used to establish the optimum c

106 rains of a quasicrystalline phase displaying face-centered icosahedral symmetry and low phason strain

107 mily of perovskite derivatives composed of a face-centered lattice of nearly isolated [BX6] units wit

108 The synthesized PMO film has a face-centered orthorhombic porous structure with a 15 nm

109 vidence for retinotopic remapping in LIP and face-centered remapping in VIP, and weaker evidence for

110 chrotron X-ray diffraction (GIXD) revealed a face-centered square grid structure with an average doma

111 ssembly of extended columns with alternating face-centered stacked structure in the solid state.

112 ture to tetragonal intermetallic [denoted as face centered tetragonal (fct)] structure.

113 is paper describes a new approach for making face-centered tetragonal (fct) FePt nanoparticles with a

114 cubic (fcc) structure to chemically ordered face-centered tetragonal (fct) structure, and further pr

115 ntered cubic phase to the chemically ordered face-centered tetragonal phase and transforms the nanopa

116 ailure to find a structure for LiBeH3 with a face-centered unit cube with edge 5.09 A, the x-ray powd