From poly(dialkylstannane)s to poly(diarylstannane)s: comparison of synthesis methods and resulting polymers

Lechner, Marie-Luise; Trummer, Markus; Bräunlich, Irene; Smith, Paul; Caseri, Walter; Uhlig, F.

doi:10.1002/aoc.1836

Cited by 15 publications

(21 citation statements)

References 36 publications

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“…It was previously shown that poly(dialkylstannane)s exhibit an absorption maximum in the region of 370e410 nm [4aec, 19,23,24], which is caused by delocalization of the s-electrons of the tin atoms along the polymer backbone. In several reports, the degree of degradation of these materials was evaluated from the UVeVis spectroscopy [4a,23,24].…”

Section: Polymer Characterization Of 18 and 19mentioning

confidence: 99%

Reduction of C,O-chelated organotin(IV) dichlorides and dihydrides leading to protected polystannanes

Khan

Komejan

Patel

et al. 2015

Journal of Organometallic Chemistry

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Section: Polymer Characterization Of 18 and 19mentioning

confidence: 99%

Reduction of C,O-chelated organotin(IV) dichlorides and dihydrides leading to protected polystannanes

Khan

Komejan

Patel

et al. 2015

Journal of Organometallic Chemistry

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“… 4 – 16 Many years later the concept was revisited and also transition metal catalysts have been applied to perform selective dehydrocoupling reactions with tin dihydrides to obtain tetraorganodistannanes or organotin polymers ( Scheme 1 ). 17 – 23 In the case of the formation of tetraorganodistannanes the formation via intermediate generation of the stannylene was proposed. 17 …”

Section: Introductionmentioning

confidence: 99%

A nitrogen-base catalyzed generation of organotin(ii) hydride from an organotin trihydride under reductive dihydrogen elimination

et al. 2015

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“…These reaction conditions afforded the polymerization of (n-Bu)2SnCl2 and (n-Oct)2SnCl2 to the polystannanes (n-Bu2Sn)n and (n-Oct2Sn)n having molar masses 8.0 × 10 3 and 6.0 × 10 3 Da respectively. The material produced from the reaction of Ph2SnCl2 under similar conditions was insoluble in organic solvents at room or elevated temperatures making molecular weight determination impossible; however the elemental composition of the isolated yellow product was in agreement with that of (Ph2Sn)n. 130 In general, there are several disadvantages of the Wurtz synthetic method; it has limited tolerance to functional groups, the yields are moderate, the reproducibility is poor and it is dangerous due to the pyrophoric nature of Na metal and harsh reaction conditions. 131…”

Section: Wurtz Couplingmentioning

confidence: 99%

“…This may be a result of steric crowding at tin as a result of the C,O-chelating ligands. Lechner et al 130 used TMEDA for the polymerization of R2SnH2 (R = nbutyl, phenyl, 4-n-butylphenyl) to polymers 251 and 252 which gave 119 Sn NMR resonance at -197 ppm, a typical region for polystannanes. Figure 57: 119 Sn NMR (C6D6) spectrum of 251.…”

Section: Non-metal Catalyzed Dehydrocouplingmentioning

confidence: 99%

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The preparation and characterization of structurally stable 5-coordinate polystannanes

Khan¹

2021

Preprint

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Tetraorganotin compounds [2-(MeOCH2)C6H4]SnR3 (R = Me, n-Bu, Ph) containing a C,O-chelating ligand were prepared in good yield from the reaction of the R3SnCl and [2-(MeOCH2)C6H4]Li. Tethered organotin compounds Ph3Sn(CH2)3OC6H4R (R = Ph, H, CF3, OCH3) were prepared in good yield from the hydrostannylation reactions of the corresponding vinyl ethers with Ph3SnH. Conversion of two organotin compounds to triorganotin chlorides and diorganotin chlorides, (Ph3-nClnSn(CH2)3OC6H4R; R = H, Ph: n = 1, 2), was successfully carried out and characterisation afforded by NMR spectroscopy. X-ray crystallographic studies revealed a tetrahedral geometry for the tetraorganotin Ph3Sn(CH2)3OC6H4CF3, while five-coordinate trigonal bipyramidal structures with relatively short Sn-O (2.7-2.8 Å) interactions were observed for both mono- (Ph2ClSn(CH2)3OC6H4R; R = H, Ph) and dichloride (PhCl2Sn(CH2)3OC6H4R; R = H, Ph) species. Penta-coordinate diorganotin dichlorides containing a C,N- chelating ligand[2-(Me2NCH2)C6H4]RSnCl2 (R = Me, n-Bu, Ph) or C,O- chelating ligand [2-(MeOCH2)C6H4]RSnCl2 (R = Me, n-Bu, Ph) were prepared by treating RSnCl3 with the lithiated salts [2-(Me2NCH2)C6H4]Li and [2-(MeOCH2)C6H4]Li respectively. Organotin chlorides were successfully reduced with LiAlH4 or NaBH4 to produce novel hydrides. Catalytic dehydrocoupling of diorganotin dihydrides to yield polystannanes was explored using a variety of dehydrocoupling catalysts such as Wilkinson’s catalyst, Cp2ZrMe2 or TMEDA. In almost every instance this resulted in the formation of yellow coloured gummy polymeric materials of moderate molecular weights (Mw = 1 × 104 - 1 × 105 Da) and PDI’s (1.3-2.0). The stability of polystannanes containing tethered O or C,N- or C,O-chelating ligands was investigated in both solid and in solution using NMR and UV-Vis spectroscopies. These studies revealed an enhanced stability to ambient light in the solid state and in solution in the dark when compared to known poly(dialkyl)stannanes.

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From poly(dialkylstannane)s to poly(diarylstannane)s: comparison of synthesis methods and resulting polymers

Cited by 15 publications

References 36 publications

Reduction of C,O-chelated organotin(IV) dichlorides and dihydrides leading to protected polystannanes

Reduction of C,O-chelated organotin(IV) dichlorides and dihydrides leading to protected polystannanes

A nitrogen-base catalyzed generation of organotin(ii) hydride from an organotin trihydride under reductive dihydrogen elimination

The preparation and characterization of structurally stable 5-coordinate polystannanes

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