ライフサイエンスコーパス: octahedral

1 planar, and 5/6-coordinate, square pyramidal/octahedral).

2 imately linear to distorted square planar to octahedral.

3 f Pt-rich and Ni-rich surface domains in the octahedral (111) facets.

4 structure but also the less common distorted octahedral 1T-WS2 structure, which exhibits metallic beh

5 ansformation from trigonal prismatic (2H) to octahedral (1T) upon lithium or sodium intercalation has

6 ical ferritin cage: a closed assembly having octahedral (4-3-2) symmetry.

7 r 5d metal) as well as a correction for d(6) octahedral acids (Cd6 = 6 for d(6) metal ion in the acid

8 state NMR spectra, consistent with the mixed octahedral Al/Zn chemical environment in typical Zn-Al L

9 ace-raised cubic, edge- and corner-truncated octahedral, all-corner-truncated rhombic dodecahedral, {

10 namely, the orthoclase (001) surface and the octahedral aluminum sheet of the kaolinite (001) surface

11 (+) (H-PNP = HN(CH2CH2P(t)Bu2)2) to generate octahedral ammine complexes that are kappa(2)-chelated b

12 ons at concentrations</=5 muM sorbed as both octahedral and tetrahedral complexes (Zn-O 1.98-2.03 A),

13 rgely present in 10-coordinate sites between octahedral and tetrahedral sites.

14 Octahedral and tetrahedral Zn (attributed to symplastic

15 h alternating layers of transition metals in octahedral and trigonal prismatic coordination and is a

16 d cuboctahedral nanocrystals of Pt(3)Ni, and octahedral and truncated octahedral nanocrystals of PtNi

17 environments for Nb (trigonal prismatic and octahedral) and smaller crystallite size, which were con

18 Cubic, rhombic dodecahedral, octahedral, and corner-truncated octahedral gold nanocry

19 Rhombic dodecahedral, octahedral, and hexapod-shaped supercrystals were genera

20 nic noble metal NCs with tetrahedral, cubic, octahedral, and icosahedral geometries have been chemica

21 engths and polyhedral symmetry--tetrahedral, octahedral, and icosahedral--are the 5 Platonic polyhedr

22 c, truncated cubic, cuboctahedral, truncated octahedral, and octahedral structures have been employed

23 c, truncated cubic, cuboctahedral, truncated octahedral, and octahedral structures.

24 nity Ca(2+) sites with trigonal bipyramidal, octahedral, and pentagonal bipyramidal coordination geom

25 hydride ligand is bridging, the Fe center is octahedral, and the Ni center is pentacoordinate.

26 his class, formed by the occupation of small octahedral B-sites within an AO3 network defined by larg

27 train can be applied to characterize complex octahedral behaviours in other advanced oxide systems.

28 The compound features octahedral [Bi(P(2)Se(6))(2)](5-) coordination complexes

29 um ions in FTase are presented, and relevant octahedral binding motifs for Mg2+ in wild-type (WT) FTa

30 ry by modifying the local distortions, i.e., octahedral bonding angle and length.

31 ons, beta and gamma phases, characterized by octahedral bonding with vdW gaps and tetrahedral bonding

32 he actinide is successively located first at octahedral brucite-like sites in the GR precursor, then

33 sorption sites around, and within, the small octahedral cage in the structure are favored over the ex

34 ns of light nitrogen atoms, each found in an octahedral cage of heavy uranium atoms.

35 ients along a (011)-like direction, the PbI6 octahedral cage will distort and the bandgap will become

36 the polar axis as a result of oversized cube-octahedral cages determined by the larger K ions.

37 twork that spans from the tetrahedral to the octahedral cages of this MOF.

38 The octahedral cation environments reveal distinct differenc

39 w that introduction of chemically mismatched octahedral cations into a cubic perovskite oxide parent

40 he existence of 6-coordinate hydrogen in the octahedral cavity of [HCo6(CO)15]- in 1979, and 5-coordi

41 of carbon- and nitrogen-centered radicals to octahedral centrochiral rhodium enolates has been invest

42 nds and acquires its chirality entirely from octahedral centrochirality.

43 " pyrochlore, in which corner-connected NbO6 octahedral chains move smoothly apart to accommodate the

44 is case is even larger than that observed in octahedral Co(2+) systems such as CoO.

45 ed by the single-ion anisotropy of elongated octahedral Co(II) sites.

46 (EXAFS) analysis of a binary mixture of the octahedral Co(III) precatalyst and [Ru(bpy)3](2+) after

47 ix different molecular clusters based on the octahedral Co6E8 (E = Se or Te) and the expanded cubane

48 The X-ray crystal structure shows an octahedral complex that adopts a facial orientation of t

49 is9, His15 and Asp17 coordinate cobalt in an octahedral complex that includes a phosphate anion, whic

50 and an aspartate coordinate manganese in an octahedral complex that includes two waters and a phosph

51 p of the primer so that the A metal is in an octahedral complex.

52 ons between the sixth ligand of these pseudo-octahedral complexes and the pendant N atom of the ring

53 The observation of liquid crystallinity in octahedral complexes of this type is without precedent.

54 For 18-electron octahedral complexes one can create the inverted situati

55 ex Fe(II) to form a series of diastereomeric octahedral complexes that are CD-active in both the UV a

56 Rhodium metalloinsertors are octahedral complexes that bind DNA mismatches with high

57 F3(-) that mimic ground-state phosphates; 2) octahedral complexes, primarily based on AlF4(-) , which

58 , of a metal ion binding mode with a coupled-octahedral configuration at the active site, exhibiting

59 l structural change from a tetrahedral to an octahedral configuration is responsible for the observed

60 e active site contains a single Mn(2+) in an octahedral coordination complex with Asp187, His189, Asp

61 o Ni(II) ions bind to the NmtR dimer to form octahedral coordination complexes with the following ste

62 The resting state structure displays an octahedral coordination for Fe(2+) with two histidine re

63 we designed a buried metal binding site with octahedral coordination geometry consisting of Bpy-Ala,

64 erves as the sixth ligand that completes the octahedral coordination geometry of the B metal ion.

65 , Mg2 recruits a water molecule to retain an octahedral coordination geometry suggesting the strong b

66 tion metal dications having a preference for octahedral coordination geometry to afford {M 8L 12} (16

67 The 6-fold, unprecedented octahedral coordination of the bromide anion generates a

68 ine residues; three water molecules complete octahedral coordination of the iron.

69 pha- and beta-phosphates of FPP complete the octahedral coordination sphere of Mg2+.

70 flexible bipyridine oligomer and a zinc(II) octahedral coordination template.

71 cluding W-W reconstruction and W-S distorted octahedral coordination, results in distinctive electric

72 al-oxygen bond length for a Co(3+) ion in an octahedral coordination.

73 incorporated in hematite in uranate, likely octahedral coordination.

74 2+) or Ni(2+) was bound by six ligands in an octahedral coordination.

75 otide and water molecules to result in ideal octahedral coordination.

76 The octahedral core of 84-electron LCuH hexamers does not di

77 core-shell structure containing a truncated octahedral core with bulk face-centered cubic-like arran

78 d a molecular model in which cobalt is in an octahedral CoS2-like state where the cobalt center is pr

79 the SL period is larger than the interfacial octahedral coupling length scale, whereas a single magne

80 esis of silicate organic frameworks based on octahedral dianionic SiO6 building units.

81 0 uc of BTO, both associated with local MnO6 octahedral distortions of the (001) LSMO within the firs

82 square pyramidal versus a vanadium(IV) in an octahedral environment featuring the same coordinating l

83 ine) features a highly rhombically distorted octahedral environment that is responsible for the stron

84 ost common cases being three below two in an octahedral environment, two below three in tetrahedral c

85 sence of framework Sn(IV)-active sites in an octahedral environment, which probably correspond to so-

86 crystal field (CF) model were applied to the octahedral f(1) complexes to determine the covalency and

87 Octahedral f(1) hexahalide complexes have been extensive

88 reinforced by a strong Ir-Ir bond across the octahedral faces, and the Ir-Ir Coulombic repulsion acro

89 ely, depending on the stereochemistry of the octahedral Fe site.

90 Self-assembly of octahedral Fe(II) ions and linear perylene bisimide (PBI

91 for As(II,III) incorporation into pyrite at octahedral Fe(II) sites and for As(-I) at tetrahedral S(

92 compound 2 constitutes the first case of an octahedral Fe(V)(N) species prepared within a neutral li

93 n are shown to be atomically sharp and of an octahedral Fe/SrO3 nature.

94 e and shell was presented with the truncated octahedral Fe3O4 nanoparticle as the core over a layer o

95 3 is a rare example of a nonheme octahedral {FeNO}(6) complex.

96 rahedral symmetry but forms a typical closed octahedral ferritin cage.

97 e-bound active site with the hydroxide-bound octahedral form shows a shifting of residue Tyr34 toward

98 ng bond distortions propagate throughout the octahedral Ga network.

99 er complexes possess tris-chelated distorted-octahedral geometries.

100 occupies the equatorial plane in an overall octahedral geometry about the rhenium(V) center.

101 The cobalt at the M1 site has a distorted octahedral geometry and is present at 100% occupancy.

102 In the solid-state, 1 adopts an octahedral geometry as shown by X-ray crystallographic a

103 The M ions in 1 and 2 have a distorted octahedral geometry by coordination with four nitrogens

104 derivatives containing mixed tetrahedral and octahedral geometry could open up new horizons in the de

105 and the strong preference for a cis-divacant octahedral geometry in four-coordinate intermediates.

106 oligonucleotides with tetrahedral or pseudo-octahedral geometry is described that involves the coupl

107 The AlF(3)(0) moiety retains the octahedral geometry observed within AlF(4)(-) TSA comple

108 as six neighboring oxygen atoms likely in an octahedral geometry with average bond lengths of 1.98 A.

109 L)2 Fe8 (PMe2 Ph)2 ] (1) displays a bicapped octahedral geometry with FeFe distances ranging from 2.4

110 ylpyrazol-1-yl)borate], exhibits a distorted octahedral geometry with Mo horizontal lineO and Mo=/--S

111 from both the arms to result in a distorted octahedral geometry with two vacant sites.

112 yme bind their respective metals with pseudo-octahedral geometry, and both may lose a histidine ligan

113 nickel sites can be described as preferring octahedral geometry, utilizing one to three protein liga

114 Ad = 1-adamantyl) confined to a cis-divacant octahedral geometry, was prepared by reduction of N3Ad b

115 decahedral, octahedral, and corner-truncated octahedral gold nanocrystals with sizes of tens of nanom

116 Octahedral group 4 bisphenolate ether complexes, activat

117 ReGV-R present a unique case of octahedral heavy-metal complexes where the S1 lifetime i

118 forms outer-sphere complexes in the aluminum octahedral interlayer of basaluminite.

119 preferentially from the stereoisomer of the octahedral intermediate, kappa(3)-Ph(CH3)(Cl)Si(ONO(Q)),

120 y the Zr/Hf clusters yielded MOFs with large octahedral interstitial cavities.

121 ent with substantial deuteron density in the octahedral, interstitial voids of the oxygen lattice.

122 netic barrier for reductive elimination from octahedral Ir(III) complexes.

123 uced substitutionally labile chiral-at-metal octahedral iridium(III) complex exclusively bears achira

124 resent in the 12-coordinate site between the octahedral iron layers, and Ca is largely present in 10-

125 nditions as a photochemical precursor for an octahedral iron nitride containing the metal at the rema

126 The octahedral iron storage enzyme, ferritin, was engineered

127 We now show that the octahedral iron(II) complexes in the molecular salt [Fe(

128 Octahedral iron(II) ions control the relative positions

129 ner-sphere surface complexes attached to the octahedral layer of (010) and (110) edge sites.

130 nd as octahedrally coordinated Zn(2+) in the octahedral layer of phyllosilicates (18-25%).

131 Al(III) in the trans-symmetric sites of the octahedral layer.

132 eferentially incorporated as Fe(3+) into the octahedral layer.

133 The reticulated Au(5)Ge octahedral layers expand in the ab plane on heating, whe

134 tes, C4N2H14PbBr4, in which the edge sharing octahedral lead bromide chains [PbBr4 (2-)]infinity are

135 kward electron transfers is stabilized by an octahedral ligand field, whereas in the solution phase a

136 ggests that the dopants reside in the vacant octahedral locations within the alumina lattice, where c

137 n Fe(II) centers of the framework convert to octahedral, low-spin Fe(II) centers upon CO coordination

138 Pseudo-octahedral M(II) 6 L4 capsules result from the subcompon

139 units (SBUs): cubic M8(mu2-O)8(mu2-OH)4 and octahedral M6(mu3-O)4(mu3-OH)4.

140 cted from oxidation likely incorporated into octahedral magnetite sites.

141 The octahedral metal complex of RtcA*ATP*Mn(2+) includes non

142 throline, threefold-symmetric triamines, and octahedral metal ions.

143 growth of In(III)- and Ga(III)-based square-octahedral metal-organic frameworks (soc-MOFs).

144 n state of the ATP alpha phosphate; a second octahedral Mg(2+) coordination complex bridges the beta

145 opic signal for this site consistent with an octahedral Mn(II) coordination sphere with simulated zer

146 splitting, characteristic of tetrahedral or octahedral Mn-O bonding.

147 tes, (ii) single crystalline manganese based octahedral molecular sieve (OMS) nanowires on silicon su

148 tudy examines the effects of manganese oxide octahedral molecular sieve chitosan microspheres (Fe3O4@

149 -2, a well-known one-dimensional microporous octahedral molecular sieve with manganese oxide framewor

150 The pseudo-octahedral molybdenum benzylidyne complex [TolC identica

151 Zn is present during struvite precipitation, octahedral monodentate sorbates detected at 1 muM (Zn-O

152 that is nearly identical to MOF-5 but has an octahedral morphology and a number of defect sites that

153 es as building blocks and possess a distinct octahedral morphology with eight {111} equivalent crysta

154 d in the common presence of titanium-centred octahedral motifs in both amorphous and crystalline Ti0.

155 hedra as templates, we obtained Pt cubic and octahedral nanocages enclosed by {100} and {111} facets,

156 als of Pt(3)Ni, and octahedral and truncated octahedral nanocrystals of PtNi.

157 o in activating and sustaining the growth of octahedral nanocrystals.

158 The norovirus P particle is an octahedral nanoparticle formed by 24 copies of the protr

159 core-shell NPs (nanorods and nanocubes) into octahedral nanorattles via room-temperature galvanic rep

160 tal structure is made up of a corner-sharing octahedral network of Ga and Ge atoms with Mn atoms at t

161 ormed through axial bridging of the in-plane octahedral Ni sites by the bidentate 1,2-bis(4-pyridyl)e

162 Interestingly, this included octahedral Ni(II) complexes which, unlike previously cha

163 on the ligands used, they possess either an octahedral (Oh) or trigonal bipyramidal ligand sphere.

164 ile, Mo geometry evolves from tetrahedral to octahedral on the edge, and back to tetrahedral coordina

165 le tetrahedral Goldberg polyhedron, a single octahedral one, and a systematic, countable infinity of

166 asier to extract from tetrahedral sites than octahedral ones.

167 yramidal for Cd(2+) and Zn(2+) and distorted octahedral or distorted tetrahedral for Cu(2+).

168 the predominance of V(4+/5+) in a primarily octahedral or tetrahedral coordination.

169 +) indicate that no preferential exchange of octahedral or tetrahedral sites occurred.

170 and DFT calculations also indicate either an octahedral or trigonal-bipyramidal complex between Zn(2+

171 This structure exhibits an unprecedented bi-octahedral (or hexagonal close packing) Au9 kernel prote

172 perature, which is unique for a Co(3+) in an octahedral oxygen surrounding.

173 of (100) facets at the vertices of truncated octahedral particles promote preferential delithiation,

174 l to cubic Pd seeds with different sizes and octahedral Pd seeds of one size to generate an array of

175 d tetrahedral Pd(II)4L8 assembly, whereas an octahedral Pd(II)6L12 cage was formed with a ligand of t

176 nvolve direct reductive elimination from the octahedral Pd(IV) centers.

177 Using a water-soluble octahedral Pd6L4 molecular cage as a host, we show that

178 h concentration of the strained metallic 1T (octahedral) phase in the as-exfoliated nanosheets.

179 it is non-stoichiometric due to a missing Fe octahedral plane.

180 valent four-coordinate tellurium atom and an octahedral platinum center.

181 Octahedral platinum(IV) complexes are promising candidat

182 We show that a new octahedral platinum(IV)-salphen complex does not interac

183 through their structural incorporation into octahedral positions of gamma-Fe2O3 (maghemite) nanopart

184 s generated by isoelectronic substitution in octahedral positions of Pb atoms by Fe within the struct

185 metric trimeric esterase into a well-defined octahedral protein cage by appending a C4-symmetric coil

186 alysts was about 50% higher than that of the octahedral Pt(3)Ni catalysts (1.26 mA/cm(2)(Pt)), even t

187 he preparation of carbon-supported truncated-octahedral Pt(3)Ni nanoparticle catalysts for the oxygen

188 The octahedral Pt(IV) complex trans,trans,trans-[Pt(N(3))(2)

189 Shape-controlled octahedral Pt-Ni alloy nanoparticles exhibit remarkably

190 ree, and cost-effective method for producing octahedral Pt-Ni alloy nanoparticles on carbon support.

191 Although octahedral Pt-Ni alloy nanoparticles possess an excellin

192 The octahedral Pt-Ni samples were prepared with different co

193 orrelated to a substantially enhanced c axis octahedral rotation (a(-)a(-)c(-), alpha~3.8 degrees , g

194 ental evidence for the interrelation between octahedral rotation and magnetism at interface is scarce

195 ervation, confirming the correlation between octahedral rotation and magnetism.

196 present work demonstrates the importance of octahedral rotation and tilt in perovskites, for influen

197 surface of Ca3Ru2O7 perovskite induced by O-octahedral rotation and tilt.

198 be expected in Ca2IrO4 due to its increased octahedral rotation and tilting, which results in enhanc

199 Here we demonstrate that interfacial octahedral rotation are closely linked to the strongly m

200 to observe two Mn sites associated with the octahedral rotation in the bulk through the "chirality"

201 eory identifies how configurations of oxygen octahedral rotation patterns, ordered cation arrangement

202 res, the structures reflect the influence of octahedral rotation.

203 ss, affecting both lattice constant and MnO6 octahedral rotation.

204 ructure (space group Imcm) featuring minimal octahedral rotations (a(-)a(-)c(-), alpha~4.2 degrees ,

205 t, the presence of modulations of the MnO(6) octahedral rotations along the growth direction commensu

206 The guidelines are based on the octahedral rotations found in the two constituent oxides

207 Lattice distortion due to oxygen octahedral rotations have a significant role in mediatin

208 tensile in-plane strain which produced weak octahedral rotations in the out-of-plane direction, an o

209 bonding tendencies, thermally activated soft octahedral rotations, and the propensity for the Pb(2+)

210 e accommodated by lattice distortions and/or octahedral rotations, ferroelectric-ferromagnetic interf

211 e and probability of the short-range ordered octahedral rotations, which resembles the pre-transition

212 transfer, intermixing, epitaxial strain, and octahedral rotations/tilts as dominating mechanisms for

213 Chemomechanical reaction: The first octahedral ruthenium bipyridine complex that bears six p

214 Octahedral ruthenium complexes [RuX(CNN)(dppb)] (1, X =

215 e ATP-binding sites by using bulky and rigid octahedral ruthenium complexes as structural scaffolds i

216 6-SBU is isostructural with the 12-connected octahedral SBUs of UiO-type MOFs, the M8-SBU is composed

217 ds: octahedrons for cuboctahedral, cubic, or octahedral seeds, and plates for platelike seeds.

218 iform cubic-phase In2O3 nanocrystals with an octahedral shape.

219 crystals, which was previously used to form octahedral shapes of Cu(2)O crystals, effectively inhibi

220 thms (shear line analysis and calculation of octahedral shear strain [OSS]) to identify the degree of

221 that Fe is located in the continuity of the octahedral sheet at trans-symmetric sites.

222 I)-Al(III)-layered double hydroxides with an octahedral sheet structure similar to nikischerite (NaFe

223 f Jahn-Teller distorted Mn(III) sites in the octahedral sheet within 0.6 ps of photoexcitation; (ii)

224 in clay minerals and electron conduction in octahedral sheets of nontronite, however, raise the ques

225 occurred in variable amounts: (1) Zn in the octahedral sheets of phyllosilicates, (2) Zn sulfide min

226 duction of Fe(II) into predominantly-Fe(III) octahedral sheets or through the adsorption of Fe(II) on

227 ally, we assessed how Fe(II) residing in the octahedral sheets, or Fe(II) adsorbed at the edge sites

228 rmine the structure of apoferritin, a smooth octahedral shell of alpha-helical subunits that is parti

229 ia an associative pathway involving neutral, octahedral silicon complex 22 with only one molecule of

230 selectivities arising from different chiral octahedral silicon complexes provide guidelines for the

231 We enclose octahedral silver nanocrystals (Ag NCs) in metal-organic

232 We used spherical, cubic, and octahedral single-crystalline gold nanoparticles as dual

233 f electrons between Ni(2+) and Ni(3+) in the octahedral site and result in an enhanced electrochemica

234 ) cations distribution and concentrations in octahedral site Fe vacancies of gamma-Fe2 O3 instead of

235 redominantly incorporated into the magnetite octahedral site in all systems studied.

236 te is Jahn-Teller (JT)-active Cu(2+) and the octahedral site is JT-active Mn(3+).

237 the eg occupancy of the active cation in the octahedral site is the activity descriptor for the ORR/O

238 (x)O(5), taking into account the tetrahedral/octahedral site preferences for the various M(3+) ions,

239 thermodynamic preference for Cr to occupy an octahedral site within a II-VI semiconductor lattice wit

240 +)-O-Na interactions into a highly distorted octahedral site.

241 f electrons between Ni(2+) and Ni(3+) in the octahedral site.

242 rahedral Cu site with compensating Cu on the octahedral site.

243 This confirms that the octahedral-site Ni(IV) /Ni(III) couple in an oxide is an

244 ysis reveals that Tc(IV) replaces Fe(III) in octahedral sites and illustrates how the resulting charg

245 diffraction data, it is determined that the octahedral sites contain a mixture of divalent Co and tr

246 occupying edge-sharing tetragonal distorted octahedral sites generated by formation of three Zn ion

247 With a series of MnCo2 O4 , the Mn in octahedral sites is identified as an active site.

248 Li sites and through intervening unoccupied octahedral sites that share faces with the LiO(4) tetrah

249 eals that Fe(3+) in Ni(1-x)Fe(x)OOH occupies octahedral sites with unusually short Fe-O bond distance

250 ual cationic sub-lattice arrangement wherein octahedral sites, which serve as bridges for cation migr

251 ations of magnesium and silicon atoms in the octahedral sites.

252 partial, Tc(IV) incorporation into magnetite octahedral sites.

253 ure, which are characterized by almost empty octahedral sites.

254 Here we show that pseudo-octahedral six-coordinate zinc porphyrin complexes can a

255 layered double hydroxide, as tetrahedral and octahedral sorbed Zn species, and as ZnS.

256 ETAE) occurred between edge-bound Fe(II) and octahedral (structural) Fe(III) within the clay lattice,

257 er of TMDCs, Mo doped ReSe2 (Mo:ReSe2) is an octahedral structure semiconductor being optically biaxi

258 Theoretical calculations revealed an octahedral structure with silver atoms occupying the cor

259 ic, cuboctahedral, truncated octahedral, and octahedral structures have been employed to form microme

260 ic, cuboctahedral, truncated octahedral, and octahedral structures.

261 CO)(7)(+) and Ta(CO)(7)(+) have C(3v) capped octahedral structures.

262 The investigation of octahedral super crystal systems provides an alternate d

263 eversible annihilation/reconstruction of the octahedral superlattice correlated with the delithiation

264 eveals a composition-dependent, self-ordered octahedral superlattice.

265 als can be systematically engineered via the octahedral superstructures leading to a modulated magnet

266 h and ferromagnetism through the creation of octahedral superstructures.

267 gn a 24-subunit, 13-nm diameter complex with octahedral symmetry and a 12-subunit, 11-nm diameter com

268 ediate its self-assembly to form hexamers of octahedral symmetry in the solid state, in solution, and

269 hat this initial excited state preserves the octahedral symmetry of the electronic ground state by de

270 e MPPNs contain 24 MscS heptamers related by octahedral symmetry.

271 nds from 24 to 48 subunits while maintaining octahedral symmetry.

272 core within a shell-like structure of 4/3/2 octahedral symmetry.

273 II), Ir(I), Rh(I), and Co(I)) and eight d(6)-octahedral systems (M = Ir(III), Rh(III), Co(III), Fe(II

274 nd tilt pattern of the corner-connected NiO6 octahedral--the structural signatures of perovskites--ow

275 This approach to quantify local octahedral tilt and correlate it with strain can be appl

276 We report changes in the octahedral tilt and lattice spacing in both materials, t

277 omic-level imaging condition to measure TiO6 octahedral tilt angles, unit-cell-by-unit-cell, in perov

278 btain a direct real-space correlation of the octahedral tilt modulation with the superstructure geome

279 re we demonstrate a violation of established octahedral tilt rules in the double perovskite analogue

280 lead, show the opposite trend: they show no octahedral tilting upon Cs-substitution but only a contr

281 ormamidinium with the smaller cesium, due to octahedral tilting.

282 % less), prevents monoclinic tilt and oxygen octahedral tilts, and increases the ferroelectric polari

283 phase occurs simultaneously with changes in octahedral tilts.

284 -Pd NP changes, step by step, from truncated-octahedral to cubic.

285 iangular, tetrahedral, trigonal dipyramidal, octahedral, to pentagonal dipyramidal.

286 s retained but becomes rate-limited when the octahedral-to-tetrahedral structural change bottlenecks

287 It was found that substitution at the octahedral transition metal site did not strongly affect

288 show that Zn(II) adsorbs as tetrahedral and octahedral triple-corner-sharing complexes at layer vaca

289 haped supercrystals at room temperature, but octahedral, truncated triangular pyramidal, and square p

290 also the first structural model involving an octahedral-type metallic cluster with gamma-CD.

291 Li(N horizontal lineC(t)BuPh), generates the octahedral U(V) ketimide complex [Li][U(N horizontal lin

292 occupied at different X sites in each Re-X6 octahedral unit cell with perfect matching between their

293 u8S12]16- clusters that behave like a pseudo-octahedral unit in the bonding pattern and are linked th

294 20 and 35 GPa and up to 800 K, features MgO6 octahedral units arranged in the anatase-TiO2 structure.

295 Despite the presence of isolated octahedral units, the close-packed iodide lattice provid

296 e-corner-sharing inner-sphere complexes over octahedral vacancies in the Mn oxide sheet structure.

297 osahedra with two oxygen atoms occupying all octahedral voids in it.

298 ged with increasing x, despite the shrinking octahedral volumes.

299 )(+) have structures slightly distorted from octahedral, while Nb(CO)(7)(+) and Ta(CO)(7)(+) have C(3

300 ous materials whose structure is composed of octahedral Zn4O(-COO)6 and triangular 1,3,5-benzenetribe