Solvent-controlled assembling by hydrogen bridges and halogen-halogen interactions of novel organotin oxo clustersElectronic supplementary information (ESI) available: Synthesis and analytical data for PhI2SnCH2SnI2Ph. See http://www.rsc.org/suppdata/cc/b1/b111337b/

Abstract: The crystal structure of the novel methylene-bridged tetraorganodistannoxane ([Ph(HO)SnCH2Sn(I)Ph]O)4 (1) depends on the solvent it is crystallised from and is controlled by hydrogen bridges and interhalogen interactions.

“…And the torsion is still indicated by the smaller O–Sn–O [71.4(2)–72.5(2)°] and larger Sn–O–Sn (114.5(3)–139.5(3)°) angles. All the bond lengths and angles are similar to those found in the complexes of the category . “Ladder” Sn 4 (μ‐O) 4 are almost coplanar, and for the steric hindrance, [(Bu 4 Sn 2 )O 2 L] 2 ladder is of the zigzag shape (Fig.…”

A Novel Tetranuclear Organotin(IV) Carboxylate with Chain Structure: Synthesis, Crystal Structure, and Characterizations

“…And the torsion is still indicated by the smaller O–Sn–O [71.4(2)–72.5(2)°] and larger Sn–O–Sn (114.5(3)–139.5(3)°) angles. All the bond lengths and angles are similar to those found in the complexes of the category . “Ladder” Sn 4 (μ‐O) 4 are almost coplanar, and for the steric hindrance, [(Bu 4 Sn 2 )O 2 L] 2 ladder is of the zigzag shape (Fig.…”

A Novel Tetranuclear Organotin(IV) Carboxylate with Chain Structure: Synthesis, Crystal Structure, and Characterizations

“…A large number of supramolecular organotin(IV) carboxylates have been prepared and structurally characterized [1,2]. Structural types such as monomers, dimers, tetramers, oligomers, and polymers have been reported [3][4][5][6][7]. The diverse structural motifs found in this family of complexes have been attributed to the nature of carboxylic acid, tin-bound R groups, and metal-ligand molar ratio [8,9].…”

Synthesis and structural characterization of monomeric and polymeric supramolecular organotin(IV) 4-chlorophenylethanoates

“…Dieses Konzept ist ebenfalls für die Chemie des Elements Zinn etabliert. Ausgewählte Repräsentanten dafür sind (RSn) 4 E 6 (R=organischer Substituent mit oder ohne zusätzliche Funktionalität, E=O, [3] S, [4] Se [4] ) mit adamantan‐ oder doppeldeckerartigen Strukturen, dodekanukleare Zinnoxocluster {(RSn) 12 O 14 (OH) 6 } (R= i ‐Pr, n ‐Bu, Me 3 SiCH 2 , Ferrocenyl), [5] Sn 12 O 8 (OH) 4 (OEt) 28 (HOEt) 4 , [6a] [(BuSn) 12 (μ 3 ‐O) 14 (μ 2 ‐OH) 6 ](L 1 ) 2 ⋅2 EtOH, [6b] [NaO 4 (BuSn) 12 (OH) 3 (O) 9 (OCH 3 ) 12 (Sn(H 2 O) 2 )], [6c] und [NaO 4 BuSn 12 (OCH 3 ) 12 (O,OH) 12 ], [6d] Tetraorganodistannoxane {R 2 (X)SnOSn(X)R 2 } 2 (R=organischer Substituent, X=elektronegativer Substituent), [7] [{R(X)Sn(CH 2 ) n Sn(X)R}O] 4 (R=organischer Substituent; X=Halogen, Hydroxid, Carboxylat; n =1, [8a] 3–8, 10, 12 [8b] ), [(R 2 SnO) 3 (R 2 SnOH) 2 CO 3 ] 2 (R=organischer Substituent), [9] und [(2,4,6‐ i ‐Pr 3 C 6 H 2 Sn) 8 (μ 4 ‐O) 2 (μ 3 ‐O) 8 ‐(μ 2 ‐O) 4 (μ 2 OH) 8 {Sn(OH)} 4 ] [10] . Kürzlich erhielt diese wohletablierte Chemie einen neuen Schub durch die von S. Dehnen et al.…”

MeSi(CH₂SnRO)₃ (R=Ph, Me₃SiCH₂): Bausteine für dreieckförmige Diorganozinnoxidmakrocyclen