and Andrzej Duda scite author profile

Kinetics of polymerization of l,l-lactide (LA) initiated with aluminum isopropoxide (Al(OiPr)3) trimer (A3) or tetramer (A4) was followed by polarimetry and by gel permeation chromatography (GPC). Results of the kinetic measurements show that A3 and A4 react with LA with different rates; namely, the k i(A 3 )/k i(A 4 ) ratios (where k i(A 3 ) and k i(A 4 ) denote the rate constants of initiation with A3 and A4, respectively) determined at 20, 50, 80 (THF solvent), and 120 °C (dioxane-1,4 solvent), are equal to 2.8 × 103, 8.0 × 102, 2.9 × 102, and 1.1 × 102, respectively. Direct observations of the A3/LA and A4/LA reacting mixtures by means of 13C NMR spectroscopy confirm this large difference of A3 and A4 reactivities in their reactions with LA. Initiation with A4 is slow enough to give polymerization that is less under control, in comparison with that initiated by A3 alone. However, due to the relatively low rate of propagation, in comparison with that of the A4 → A3 transformation, the apparent rates of LA polymerization initiated with A3 or A4 tend to converge, particularly at higher monomer conversion degrees (>90 mol %) and at higher temperatures, suggesting that also the less reactive A4 is eventually transformed into the tris(macroalkoxide) ((...−C(O)CH(CH3)O)3Al) growing species almost completely. Molecular weight (M̄ n), polydispersity index (M̄ w/M̄ n), and kinetic measurements of the A3-initiated LA polymerization reveal a living character of this process: initiation is fast and quantitative, each −OiPr group of A3 starts growth of one macromolecule, and the concentration of the resulting active centers remains constant. On the other hand, propagation exhibits fractional order (e.g., equal to 0.7 at 80 °C in THF solvent) in active centers. Therefore, kinetic data were analyzed by assuming that the actually propagating active species (P n *) aggregate reversibly into the unreactive dimers.

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Mechanism of Cyclic Ester Polymerization Initiated with Tin(II) Octoate. 2. Macromolecules Fitted with Tin(II) Alkoxide Species Observed Directly in MALDI−TOF Spectra

Kowalski

2000

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Polymerization of -caprolactone (CL) initiated with tin(II) octoate (tin(II) 2-ethylhexanoate, (Sn(Oct)2)) in the presence of butyl alcohol (BuOH) or water and conducted in tetrahydrofuran (THF) as a solvent at 80 °C was studied using MALDI-TOF mass spectrometry. Formation of the following populations of macromolecules was revealed:and macrocyclics with incorporated tin(II) alkoxide moieties [O(O)C(CH2)5]nOSn. Thus, the most rewarding has been a direct observation of species with a tin atom covalently bonded with the polyester chain, at least for two populations of macromolecules (i.e., Bu[O(O)C(CH2)5]nOSnOct and [O(O)C( CH2)5]nOSn cyclics). Identification of the tin-containing macromolecules was based not only on the agreement between the observed m/z and the calculated molar mass values but also on the particular isotopic distribution provided by the tin atom. This result is in favor of the mechanism postulating propagation on the tin(II) alkoxide as the active center.

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Polymerization of l,l-Dilactide Initiated by Tin(II) Butoxide

et al. 2000

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The kinetics and mechanism of L,L-dilactide (LA) polymerization, initiated with tin(II) butoxide (Sn(OBu)2) and carried out in THF solvent (from 20 to 80 °C) or in bulk (at 120 °C), were studied. Polarimetric and size exclusion chromatography (SEC) measurements showed that initiation was fast and quantitative; termination and intramolecular transesterification (backbiting) were not observed. According to the 1 H NMR and MALDI-TOF spectra analysis, both alkoxide groups in Sn(OBu)2 were converted into poly(L-lactide) (PLA) growing chains, and monomer addition proceeded with the acyloxygen bond scission. SEC and osmometric measurements revealed that number-average molar masses (Mn) of PLA chains were equal to the ratio 144.13([LA]0 -[LA])/2[Sn(OBu)2]0 in the range of Mn from 10 3 up to ≈10 6 . Propagation was first order (internally) in LA; it was also approximately first order in initiator (at least for [Sn(OBu)2]0 > 10 -3 mol L -1 ). The rate constant of propagation (kp, for one macroalkoxide chain) was equal to 0.5 mol -1 L s -1 (THF, 80 °C). Agreement of the kinetic plots determined by SEC and polarimetry indicated that racemization did not take place. The kp/ktr2 ) 125 (where ktr2 is the intermolecular transesterification rate constant) was measured at 80 °C, belonging to the highest values from those determined until now.

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and Andrzej Duda

Polymerization of l,l-Lactide Initiated by Aluminum Isopropoxide Trimer or Tetramer

Mechanism of Cyclic Ester Polymerization Initiated with Tin(II) Octoate. 2. Macromolecules Fitted with Tin(II) Alkoxide Species Observed Directly in MALDI−TOF Spectra

Polymerization of l,l-Dilactide Initiated by Tin(II) Butoxide

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