Thermal ellipsoids

ORTEP = Oak Ridge Thermal Ellipsoid Plotting Program. With regard to / -values see Sec. 6.2. 

Figure 19 ORTEP diagram (35% thermal ellipsoids) with atom labelling of (CN-[3-(2-pyridyl)-2-thienyl] tri(p-tolyl)tin(IV). " ...

Structure 1. Ortep diagram (50% thermal ellipsoids) showing the solid state structure for 19... 

Fig. 5.10 (a) Coordination environment of the Cs cation in Cs[(Zr6B)Cl2.2ln.8]- (b) Distorted octahedral halide environment of the Na cation in Na[(Zr6B)Cl3.9lio.i] (a), thermal ellipsoids with 50% probability. 

Fig. 5.17 View of the structure of the orthorhombic mixed-halide cluster phase Cs2[ Zr6B)CbT.98l3.02] showing the two types of cluster chains (thermal ellipsoids with 50% probability). Cs cations and inner halides are omitted for clarity.

Fig. 5.18 View of the structure of Cs2[(Zr6B)ClT 1.9813.02] along a showing the Cs cation sites as located in channels along the view direction. Thermal ellipsoids are draws at the 50% level.

Fig. 5.19 View of the triclinic structure of the mixed-halide A [(Zr6Z)(CI,l)i8] phase (here with Z = Fe), which consists of molecular cluster units (thermal ellipsoids with 50% probability).

Figure 1.5 Thermal ellipsoid plot of [Au4(ArNC(H)NAr)4], Ar = 4-OMe-CgH4.

Figure 1.12 Thermal ellipsoid plot of [Au2(2,6-Me2Ph-form)2].

Figure 1.20 (a) Thermal ellipsoid plot and bond distances and angles of [Au2(2,6-Me2Ph-form)2].2Hg(CN)2-2THF. (b) 2D of [Au2(2,6-Me2Ph-form)2].2Hg(CN)2 2THF showing the TFIF solvent in the voids. 

Figure 1.26 Thermal ellipsoid plot of [Au4(3,5-Ph2pz)3(2,6-Me2-form)].

Figure 1.40 Thermal ellipsoid drawing of the stacked octafluoronaphthalene with Au3(p-tolN = COEt)3.

Figure 5.1 Thermal ellipsoid drawing of [(TPA)AuCI] CH3CN in 50% probability. Reproduced with permission from [22], Copyright (1995) American Chemical Society.

Figure 5.18 (a) Drawing of the [Au(S2CN (C5Hii)2)]2 molecules in DMSO with two repeating units of chains in the structure viewed perpendicular to the stacking axis. Thermal ellipsoids are drawn at the 50% probability level. The pentyl moieties have been omitted forclarity. 

Fig 51. Thermal ellipsoids for the series [TpBu JZnCl nl, as the result of refining as (i) Cl (upper row), (ii) I (lower row), and (iii) a composite atom (middle row). Reprinted with permission from Ref. (83). Copyright 1991 American Chemical Society. 

Fig. 2. Thermal ellipsoidal drawing of [Mes2BB(Ph)Mes)2 which contains formal boron-boron double bonds. [Reprinted with permission from Moezzi et al.9 Copyright 1992 American Chemical Society.]...

Fig. 3. Thermal ellipsoidal drawing50of [R2AIAIR2] (R = CH(SiMe3)2). Important structural details are given in Table II.

Fig. 4. Thermal ellipsoidal drawing45 of [Li(12-crown-4)2]+ [Trip2GaGaTrip2]. Important bond distances and angles for this compound, and its aluminum analog, are given in Table II.

Fig. 10. Thermal ellipsoidal plot of Mes GaNHPh showing the alignment between the coordination planes of N and Ga and the distortion in one of the Mes rings. Further details are given in Table III. [Reprinted with permission from Brothers et al.60b Copyright 1994 American Chemical Society.]...

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