Mika Härkönen scite author profile

The synthesis of low molecular weight (M n (NMR) < 7000 g/mol) lactic acid prepolymers by condensation polymerization of l-lactic acid was investigated. Besides the l-lactic acid polymer, hydroxyl- and carboxyl-terminated telechelic prepolymers were also prepared by the addition of small amounts of 1,4-butanediol and adipic acid, respectively. All polymerizations were carried out in a melt with tin octoate as the catalyst. The products were characterized by differential scanning calorimetry, gel permeation chromatography (GPC), IR, 1H-NMR, and 13C-NMR. According to NMR, the resulting prepolymers contained less than 1 mol % of lactic acid monomer and less than 4.1 mol % of lactide. End group analysis of the polymers was carried out by comparing the NMR spectra of different polymers. According to NMR, the lactic acid can be copolymerized so that the resulting prepolymer chains have only one kind of end group, hydroxyl or carbonyl. The integrated area of the identified end group peak (hydroxyl or acid) was then used in molecular weight calculations. In 13C-NMR studies, the molecular weights were calculated by using the peaks in the methine area. The molecular weights were also calculated by using the peak integrals of 1H-NMR spectra of different polymers. The calculated molecular weights were systematically smaller than the molecular weights determined by GPC, and on about the same order as the molecular weights determined by titrimetric methods. The number-average molecular weights of prepared prepolymers determined by GPC varied from 2800 to 18 000 g/mol, depending on the amount of difunctional substance added. The glass transition temperatures varied from 16.7 to 46 °C.

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Effect of Catalyst and Polymerization Conditions on the Preparation of Low Molecular Weight Lactic Acid Polymers

Hiltunen¹,

Seppälä²,

Härkönen³

1997

Macromolecules

100

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The synthesis of low molecular weight (M̄ n(NMR) < 27 000 g/mol) lactic acid polymers by condensation polymerization of l-lactic acid was investigated. All polymerizations were carried out in the melt, using different catalysts and polymerization temperatures. The products were characterized by DSC, GPC, titrimetric methods, and 13C-NMR. According to NMR, the resulting polymers contained less than 1 mol % of lactic acid monomer and less than 6.6 mol % of lactide. In 13C-NMR studies, the molecular weights were calculated by using the previously identified end group peaks in the methine area. The calculated molecular weights were systematically smaller than the weight-average molecular weights determined by GPC and on the same order as the molecular weights determined by titrimetric methods. The weight-average molecular weights of prepared prepolymers determined by GPC varied from 3600 to 32 600 g/mol, depending on the catalyst and polycondensation conditions. In DSC studies the glass transition temperatures of the resulting polymers varied from 24 to 51 °C, and crystallinity varied from 0% to 52%. The annealing of the polymer samples had only a small effect on glass transition temperatures and crystallinity. According to our results, the best polycondensation catalyst was sulfuric acid, which produced the highest molecular weights and over 50% crystallinity. Sn(II) octoate produced quite a high molecular weight polymer which was totally amorphous (the proportion of d-lactic acid structures was about 48 mol %).

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Lactic acid based poly(ester‐urethanes): Use of hydroxyl terminated prepolymer in urethane synthesis

Hiltunen¹,

Seppälä²,

Härkönen³

1997

J. Appl. Polym. Sci.

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: We studied a two step process for lactic acid polymerization: in the first step, the lactic acid is condensation polymerized to a low molecular weight hydroxyl terminated prepolymer and then the molecular weight is raised by joining prepolymer chains together using diisocyanate as the chain extender. The resulting polymer is a thermoplastic poly(ester-urethane). The polymer samples were carefully characterized with 13 C-NMR, GPC, DSC, and IR. The results indicate that high conversions of lactic acid can be achieved, as well as independent control of the stereostructure, long chain branches, molecular weight average, and molecular weight distribution. Lactic acid is converted into a poly(ester-urethane) with a weight average molecular weight as high as 390,000 g/mol and a glass transition temperature of 53.7ЊC. The analyzed content of the monomer in the prepolymer is less than 1 mol % and the lactide content 2.4 mol %, while the final poly(ester-urethane) is essentially monomer and lactide free. The mechanical properties of the poly(ester-urethane) are comparable to those of polylactides.

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Effect of the structure of external alkoxysilane donors on the polymerization of propene with high activity Ziegler‐Natta catalysts

Seppälä¹,

Härkönen²,

Luciani

1989

Makromol. Chem.

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Propene was polymerized in bulk in the presence of high activity heterogeneous Ziegler-Natta catalyst with the purpose of finding correlations between the structure of' an external alkoxysilane donor and the polymer. Nineteen silane compounds (1-8) of the structure R,lSi(OR)4.,l, where n = 1-4, R=C,H,, alkyl or H; R' = C,_,-alkyl, were used as external donors. The effect of Si/AI mole ratio was studied. The effect of the external alkoxysilane donor on the polymerization strongly depends on the number and size of alkoxy groups and the size of hydrocarbon groups attached to the silicon atom. Two major effects were observed: selective deactivation of atactic active centers and the increased production of high-molecular-weight isotactic polypropylene.Evidently, at least one free non-hindered alkoxy group in the complex between alkoxysilane and AIEt, is required for the selective deactivation. Also, the size of the hydrocarbon group of the donor strongly influences the selectivity of the deactivation. 0025.1 16)

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Lactic acid based poly(ester-urethanes): Use of hydroxyl terminated prepolymer in urethane synthesis

Hiltunen¹,

Seppälä²,

Härkönen³

1997

J. Appl. Polym. Sci.

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We studied a two step process for lactic acid polymerization: in the first step, the lactic acid is condensation polymerized to a low molecular weight hydroxyl terminated prepolymer and then the molecular weight is raised by joining prepolymer chains together using diisocyanate as the chain extender. The resulting polymer is a thermoplastic poly(ester-urethane). The polymer samples were carefully characterized with 13 C-NMR, GPC, DSC, and IR. The results indicate that high conversions of lactic acid can be achieved, as well as independent control of the stereostructure, long chain branches, molecular weight average, and molecular weight distribution. Lactic acid is converted into a poly(ester-urethane) with a weight average molecular weight as high as 390,000 g/mol and a glass transition temperature of 53.7ЊC. The analyzed content of the monomer in the prepolymer is less than 1 mol % and the lactide content 2.4 mol %, while the final poly(ester-urethane) is essentially monomer and lactide free. The mechanical properties of the poly(ester-urethane) are comparable to those of polylactides.

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Mika Härkönen

Synthesis and Characterization of Lactic Acid Based Telechelic Prepolymers

Effect of Catalyst and Polymerization Conditions on the Preparation of Low Molecular Weight Lactic Acid Polymers

Lactic acid based poly(ester‐urethanes): Use of hydroxyl terminated prepolymer in urethane synthesis

Effect of the structure of external alkoxysilane donors on the polymerization of propene with high activity Ziegler‐Natta catalysts

Lactic acid based poly(ester-urethanes): Use of hydroxyl terminated prepolymer in urethane synthesis

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