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106 4 Synthesis, Properties, and Mathematical Modeling of Biodegradable Aliphatic Polyesters
References
1. Hakkarainen, M. (2002) Aliphatic poly(propylene dicarboxylate)s: effect
polyesters: abiotic and biotic degra- of chain length on thermal properties
dation and degradation products. Adv. and crystallization kinetics. Polymer, 48,
Polym. Sci., 157, 113–138. 3125–3136.
2. Müller, R.J. (2003) in Biopolymers,Gen- 11. Umare, S.S., Chandure, A.S., and
eral Aspects and Special Applications, Pandey, R.A. (2007) Synthesis, char-
vol. 10 (ed A. Steinbüchel), Wiley-VCH acterization and biodegradable studies of
Verlag GmbH, Weinheim, pp. 365–374. 1,3-propanediol based polyesters. Polym.
3. Platt, D.K. (2006) Biodegradable Poly- Degrad. Stab., 92, 464–479.
mers. Market Report. Smithers Rapra 12. Forschner, T.C. and Gwyn, D.E. (1999)
Limited, Shawbury. Utilization of 1,3-Propanediol in Ther-
4. Freund, A. (1881) Uber die Bildung und moplastic Polyurethane Elastomers
Darstellung von Trimethylenalkohol TPUs, Shell Chemicals Ltd.
aus Glycerin. Monatsh. Chim., 1881, 13. Saxena, R.K., Anand, P., Saran, S., and
636–641. Jasmine, I. (2009) Microbial production
5. Chuah, H. (1996) Corterra polytrimethy- of 1,3-propanediol: Recent developments
lene terephthalate-new polymeric and emerging opportunities. Biotechnol.
fiber for carpets. Chem. Fibers Int., Adv., 27, 895–913.
46, 424–428. 14. Tsunoda, T. and Nomura, K. (2002)
6. Papageorgiou, G.Z., Achilias, D.S., Process for producing 1,3-propanediol
Karayannidis, G.P., Bikiaris, D.N.,
through acrolein hydration and hydrox-
Roupakias, C., and Litsardakis, G. (2006) ypropanal hydrogenation and active
Step Scan TMDSC and High Rate DSC
hydration catalysts for use in the pro-
study of the multiple melting behavior
cess. WO Patent 2002070447, PCT
of poly(1,3-propylene terephthalate). Eur.
International Applications.
Polym. J., 42, 434–445.
15. Lange, J.P. (2001) Process and catalyst
7. Karayannidis, G.P., Roupakias, C.,
system for preparing a 1,3-diol by the
Bikiaris, D.N., and Achilias, D. (2003)
hydrogenation of a 3-hydroxyaldehyde.
Study of various catalysts in the syn-
WO Patent 2001070658, PCT Interna-
thesis of poly(propylene terephthalate)
tional Applications
and mathematical modeling of the
16. U.S., E.U (2007) Biodiesel Fuel Market
esterification reaction. Polymer, 44,
Currentand Future Outlooks.Reportby
931–942.
Fuji-Keizai USA Inc.
8. Roupakias, C.P., Bikiaris, D.N., and
17. Leja, K., Czaczyk, K., and Myszka,
Karayannidis, G.P. (2005) Synthe-
K. (2011) The use of microorganisms
sis, thermal characterization, and
in 1,3-propanediol production. Afr. J.
tensile properties of alipharomatic
Microb. Res., 5, 4652–4658.
polyesters derived from 1,3-propanediol
and terephthalic, isophthalic, and 18. Kurosaka, T., Maruyama, H.,
2,6-naphthalenedicarboxylic acid. J. Naribayashi, I., and Sasaki, Y. (2008)
Polym. Sci., Part A: Polym. Chem., 43, Production of 1,3-propanediol by
3998–4011. hydrogenolysis of glycerol catalyzed
9. Bikiaris, D.N., Papageorgiou, G.Z., by Pt/WO /ZrO . Catal. Commun., 9,
2
3
Giliopoulos, D.J., and Stergiou, C.A. 1360–1363.
(2008) Correlation between chemical 19. Kubiak, P., Leja, K., Myszka,
and solid state structures and enzy- K., Celinska, E., Spychała, M.,
matic hydrolysis in novel biodegradable Szymanowska-Powałowska, D., Czaczyk,
polyesters. The case of poly(propylene K., and Grajek, W. (2012) Physiological
alkanedicarboxylate)s. Macromol. Biosci., predisposition of various Clostridium
8, 728–740. species to synthetize 1,3-propanediol
10. Soccio, M., Lotti, N., Finelli, L., Gazzano, from glycerol. Process Biochem., 47,
M., and Munari, A. (2007) Aliphatic 1308–1319.
