Octahedral Adducts of Dichlorosilane with Substituted Pyridines: Synthesis, Reactivity and a Comparison of Their Structures and ²⁹Si NMR Chemical Shifts

Abstract: H(2)SiCl(2) and substituted pyridines (Rpy) form adducts of the type all-trans-SiH(2*)Cl(2)2 Rpy. Pyridines with substituents in the 4- (CH(3), C(2)H(5), H(2)C=CH, (CH(3))(3)C, (CH(3))(2)N) and 3-positions (Br) give the colourless solids 1 a-f. The reaction with pyrazine results in the first 1:2 adduct (2) of H(2)SiCl(2) with an electron-deficient heteroaromatic compound. Treatment of 1 d and 1 e with CHCl(3) yields the ionic complexes [SiH(2)(Rpy)(4)]Cl(2*)6 CHCl(3) (Rpy=4-methylpyridine (3 d) and 4-ethylpyri… Show more

“…In previous studies we have also recognized this coordinative behavior of bond lengthening upon Cl vs. F substitution [19]. It can be interpreted as enhanced O and N donor action in chlorosilicon complexes owing to the longer Si−Cl bond with pronounced ionic contributions [20].…”

Photo‐Driven Si‐C Bond Cleavage in Hexacoordinate Silicon Complexes 

“…In previous studies we have also recognized this coordinative behavior of bond lengthening upon Cl vs. F substitution [19]. It can be interpreted as enhanced O and N donor action in chlorosilicon complexes owing to the longer Si−Cl bond with pronounced ionic contributions [20].…”

Photo‐Driven Si‐C Bond Cleavage in Hexacoordinate Silicon Complexes 

“…This ligand, H 2 L, has already been reported in the literature [85] and was synthesized by condensation of o-phenylenediamine with two equivalents of pyrrole-2-carbaldehyde (Scheme 2). Prior to reacting with the chlorosilanes to be chelated upon substitution of two Cl atoms [SiCl 4 , PhSiCl 3 , Ph 2 SiCl 2 , (Anis) 2 SiCl 2 and (4-Me 2 N-C 6 H 4 )PhSiCl 2 ], H 2 L was converted into its bis(trimethylsilyl) derivative (Me 3 Si) 2 L, as its conversion with further chlorosilanes (in a transsilylation reaction) produces chlorotrimethylsilane as a liquid and volatile byproduct, which allows for easy separation from the target complex. Whereas SiCl 4 , PhSiCl 3 , and Ph 2 SiCl 2 were commercially available, (Anis) 2 SiCl 2 and (4-Me 2 N-C 6 H 4 )PhSiCl 2 were prepared from SiCl 4 and PhSiCl 3 , respectively, and suitable Grignard reagents (see Experimental Section).…”

“…Prior to reacting with the chlorosilanes to be chelated upon substitution of two Cl atoms [SiCl 4 , PhSiCl 3 , Ph 2 SiCl 2 , (Anis) 2 SiCl 2 and (4-Me 2 N-C 6 H 4 )PhSiCl 2 ], H 2 L was converted into its bis(trimethylsilyl) derivative (Me 3 Si) 2 L, as its conversion with further chlorosilanes (in a transsilylation reaction) produces chlorotrimethylsilane as a liquid and volatile byproduct, which allows for easy separation from the target complex. Whereas SiCl 4 , PhSiCl 3 , and Ph 2 SiCl 2 were commercially available, (Anis) 2 SiCl 2 and (4-Me 2 N-C 6 H 4 )PhSiCl 2 were prepared from SiCl 4 and PhSiCl 3 , respectively, and suitable Grignard reagents (see Experimental Section). [7][8][9][10][11]18,19,[73][74][75][76][77] chelators, we have now explored silicon coordination chemistry with a dianionic tetradentate (N,N′,N′,N) chelator.…”

“…Whereas SiCl4, PhSiCl3, and Ph2SiCl2 were commercially available, (Anis)2SiCl2 and (4-Me2N-C6H4)PhSiCl2 were prepared from SiCl4 and PhSiCl3, respectively, and suitable Grignard reagents (see Experimental Section). Complexes LSiCl 2 , LSiPhCl, LSiPh 2 , LSi(Anis) 2 and LSiPh(4-Me 2 N-C 6 H 4 ) were obtained as orange solids that exhibited poor solubility in various organic solvents. Therefore, the emphasis of characterization is put on solid-state methods ( 29 Si CP/MAS NMR spectroscopy, single-crystal X-ray diffraction) and computational methods.…”

“…Whereas the former preferentially bind to Si atoms that carry strongly electron withdrawing groups (e.g., formation of pyridine adducts of halosilanes, Scheme 1, A, [1][2][3]), the latter offer greater opportunities of creating five-and six-coordinate silicon compounds even in case of the absence of halides from the silicon coordination sphere (e.g., pentacoordinate silicon with SiC 5 coordination sphere, B [4][5][6]; and hexacoordinate silicon with a tetradentate chelator and two Si-CH 3 groups, C [7]). For various reasons, such as activation of Si-X bonds by silicon hypercoordination [8][9][10][11][12][13][14][15][16], exploring special electronic/optical properties arising from the higher coordination number of silicon in combination with selected ligands [17][18][19][20] or the aim of creating and exploring hitherto unusual Si coordination compounds, e.g., with transition metals [21][22][23][24][25][26][27][28][29] or very soft Lewis bases in their ligand sphere [30][31][32][33][34][35][36][37][38], silicon coordination chemistry continues to be an attractive research field, reflected by frequently published research articles [39][40]…”

Hexacoordinate Silicon Compounds with a Dianionic Tetradentate (N,N′,N′,N)-Chelating Ligand

Sol–gel derived Si/C/O/N‐materials: molecular model compounds, xerogels and porous ceramics