ライフサイエンスコーパス: octahedron

1 u(II) complexes exhibit an axially elongated octahedron.

2 ng between the cation and the halides in the octahedron.

3 roups at the equatorial plane of a single Fe octahedron.

4 ly stable M6 O21 units connected by a single octahedron.

5 rlayer space are surrounded by a regular As6 octahedron.

6 dra and two large tetrahedra that contact an octahedron.

7 lso be reversibly converted to the molecular octahedron.

8 gand substitution reactions on the molecular octahedron.

9 ligands bridge each Rh-Rh edge of a regular octahedron.

10 dynamics simulations for the tetrahedron and octahedron.

11 )(3)) groups bridging two edges of the Ru(6) octahedron.

12 o longer distances that generate a distorted octahedron.

13 ated with an in-plane rotation of the RuO(6) octahedron.

14 er transition for the rest of the Sb-centred octahedrons.

15 ubic seeds grew into cuboctahedrons and then octahedrons.

16 le (Ag(24)) shells are octahedral (O(h)), an octahedron (a Platonic solid with six 3.3.3.3 vertices)

17 ow five distinct polyhedra-a tetrahedron, an octahedron, a cube, a cuboctahedron, and a triangular pr

18 d with six 3.3.3.3 vertices) and a truncated octahedron (an Archimedean solid with twenty-four 4.6.6

19 The frame is a DNA origami octahedron and can be used to fabricate clusters with va

20 tions confirm the exponential growth of both octahedron and catalyst replicas.

21 enables the reversible distortion of TMO(6) octahedron and mitigates TM dissolution and migration.

22 atoms are shared with the vertices of a FeO6 octahedron and of a phosphate tetrahedron.

23 edron folded with M13 transcript RNA, and an octahedron and pentagonal bipyramids folded with 23S rib

24 t repeat tiling unit consists of one regular octahedron and six smaller regular tetrahedra.

25 In the case of octahedron and triangle combinations, MOFs based on pyri

26 nvolution of three basic types: tetrahedron, octahedron, and cube.

27 (t)(3)) group bridging one edge of the Ru(6) octahedron, and the other is a triple bridge.

28 nd release of stress derived from the MnN(6) octahedrons are unilaterally restrained.

29 is but also provides, for the first time, Ag octahedrons as small as 40 nm in edge length for optical

30 e edges of a cube containing an isolated M-X octahedron at its body center.

31 Vacancies make the rigid TMO(6) octahedron become more asymmetric and flexible.

32 id state manifests the shape of an imperfect octahedron, built by Cu [Formula: see text] surfaces, co

33 A structures, such as a cube and a truncated octahedron, but these DNA constructs represent regular g

34 natase TiO(2) , thereby shortening staggered octahedron chains to form an amorphous buffer layer on t

35 mix of {100} and {111} facets and eventually octahedrons completely covered by {111} facets.

36 The chromium centers possess octahedron coordination comprised of oxygen-based ligati

37 bimetallic nanoparticles (NPs) having a gold octahedron core and a palladium epitaxial shell with con

38 non-tiling Platonic solids (the tetrahedron, octahedron, dodecahedron and icosahedron) in three-dimen

39 cal cis-ordering of the two nitrides in each octahedron driven by covalency, which results in disorde

40 er length scales exceeding approximately one octahedron due to disorder in the inter- and intraoctahe

41 individual struts is not repeated in a given octahedron, each strut is uniquely addressable by the ap

42 ic in shape), we could selectively obtain Ag octahedrons enclosed by {111} facets and nanocubes/nanob

43 a 5-nm cage-like structure, an omnitruncated octahedron filled with well-ordered ice-like water molec

44 ng messenger RNA and de Bruijn sequences, an octahedron folded with M13 transcript RNA, and an octahe

45 pending on the shapes of the Pd or Pt seeds: octahedrons for cuboctahedral, cubic, or octahedral seed

46 from octahedron-shaped nanoparticles, and an octahedron habit from rhombic dodecahedron-shaped nanopa

47 ology using a preassembled soluble molecular octahedron has been realized experimentally.

48 ral catenanes, such as a cube or a truncated octahedron, have been assembled from branched junctions.

49 anoclusters and high-index facet Mn3 O4 nano-octahedrons (hi-Mn3 O4 ).

50 igami nanoparticles including a tetrahedron, octahedron, icosahedron, cuboctahedron and reinforced cu

51 o various polyhedra (dodecahedron, truncated octahedron, icosahedron, truncated icosahedron).

52 lation between the distortion of the "PbBr6" octahedron in the 2D layer and the broadening of PL emis

53 4] molecular building block (MBB) with a Zn6 octahedron inscribed in a Zn8 cube.

54 The octahedron is completed with two CO ligands and CN(-), w

55 The metal-halide ionic octahedron is the optoelectronic unit for halide perovsk

56 a) perovskite, containing corner-shared IrO6 octahedrons, is designed.

57 h corner-shared and under-coordinated IrO(x) octahedrons, is responsible for the observed high activi

58 n toluene affords the neutral aromatic Ga(6) octahedron L:Ga[Ga(4)Mes(4)]Ga:L (3).

59 One displaced MoO(n) octahedron might serve as nucleation site for an inhomog

60 the rich chemistry of the metal halide ionic octahedron [MX(6)](n-) (M = Pb(2+), Sb(3+), Te(4+), Sn(4

61 ergo reversible geometric conversion between octahedron (NiO(6)) and square planar (NiO(4)) to achiev

62 of inorganic slab (composed of [PbI(6)](4-) octahedrons) numbers on regulating the thickness and qua

63 anocube (NC), rhombic dodecahedron (RD), and octahedron (OC) - exposing {100}, {110}, and {111} facet

64 N-H...O-S hydrogen bonds to form a truncated octahedron, one of the Archimedean polyhedra.

65 without any transitions in either the VO(6) octahedrons or the V 3d t(2g) and e(g) states.

66 o be enclosed by {111} facets in the form of octahedrons or thin plates, depending on the shapes of t

67 f the triangular facets of a tetrahedron, an octahedron, or an icosahedron with the T vertices and co

68 Then we construct a one-parameter family of octahedron packings that continuously spans from the fcc

69 or Pt seeds (in the shape of cuboctahedrons, octahedrons, plates, or cubes) together with a weak redu

70 the parent structure; concentration of this octahedron reconstitutes the original cuboctahedron.

71 onstruct interactions that self-replicate an octahedron, requiring a two-particle dimer for a catalys

72 -bound crown ethers with the [M(IV)X(6)](2-) octahedron resulted in a structurally and optoelectronic

73 space-filling polyhedrons, namely, truncated octahedrons, rhombic dodecahedrons, hexagonal prisms, cu

74 Using trilinear coupling of two types of octahedron rotation, hybrid improper ferroelectricity ha

75 how how breaking the traditional paradigm of octahedron-rotation based structure distortions in 2D or

76 approach, it is observed that the truncated octahedron shape adopted by bare Pt nanoparticles underg

77 particles, a rhombic dodecahedron habit from octahedron-shaped nanoparticles, and an octahedron habit

78 It is shown that every face of the Al(6)(2-) octahedron still possesses both pi- and sigma-aromaticit

79 nthetic oligodeoxynucleotides, folds into an octahedron structure by a simple denaturation-renaturati

80 ominated and bending dominated cells such as octahedron, tetrahedron and octet have been designed for

81 which possesses a unique edge-sharing Ti4O17 octahedron tetramer core, is stabilized by the constrain

82 The material is built up from a TiO(6) octahedron that is linked to six IO(3) polyhedra.

83 l shapes of Platonic solids (tetrahedron and octahedron) that can be occupied by a variety of solvent

84 nearest neighbor sixfold (distorted) oxygen octahedron; the Fe-O distances, while slightly different

85 pexes of an extremely tetragonally elongated octahedron; the polyhedra share oxide vertexes.

86 dge-sharing [MQ(6)](8-) octahedra that are 1-octahedron-thick and connected via van der Waals bonding

87 nitely in one direction, confined to being 1-octahedron-thick in the second direction, with n control

88 ating cation is to stabilize the lead iodine octahedron through coordination with exposed lead ions a

89 e first step in this progression from an NCS octahedron to an inorganic NCS solid is the formation of

90 ahedra can be combined with a single regular octahedron to tile (complete fill) three-dimensional Euc

91 show that these polyhedral blocks--cubes and octahedrons--when mixed with spheres, promote the assemb

92 sforms this cuboctahedron into two identical octahedrons, which upon further dilution convert into fo

93 major product; X-ray diffraction shows a Cu6 octahedron with one face capped by an additional Cu.

94 The truncated octahedron, with an interior volume of 2200 cubic angstr