Abstract
This study is an attempt to develop a theoretical methodology to elucidate or predict the structural characteristics and the physical properties of an isolated polymeric chain and its crystalline state precisely and quantitatively. To be more specific, conformational characteristics of a biobased and biodegradable polyamide, nylon 4, in the free state have been revealed by not only ab initio molecular orbital calculations on its model compound but also nuclear magnetic resonance experiments for the model and nylon 4. Furthermore, the crystal structure and solid-state properties of nylon 4 have been elucidated by density functional theory calculations with a dispersion force correction under periodic boundary conditions. In the free state, the nylon 4 chain forms intramolecular N–H···O=C hydrogen bonds, which force the polymeric chain into distorted conformations including a number of gauche bonds, whereas nylon 4 crystallizes in the fully extended all-trans structure (α form) that is stabilized by intermolecular N–H···O=C hydrogen bonds. The intermolecular interaction energy (ΔECP) in the crystal was accurately calculated via a counterpoise (CP) method contrived here to correct the basis set superposition error, and the ultimate crystalline modulus (Eb) in the chain axis (b axis) direction at 0 K was also evaluated theoretically. The results were compared with those obtained from the α and γ crystalline forms of nylon 6, and, consequently, the superiority of nylon 4 to nylon 6 in thermal stability and mechanical properties was indicated: the ΔECP and Eb values are, respectively, −214 cal g–1 and 334 GPa (nylon 4), −191 cal g–1 and 316 GPa (α form of nylon 6), and −184 cal g–1 and 120 GPa (γ form of nylon 6). In conclusion, nylon 4 is expected to be put to practical use as a tough environmentally friendly polyamide.
Highlights
In order to suppress global warming, we are increasingly required to replace chemical production based on fossil resources with manufacture from carbon-neutral feedstock
The nylon 4 chain forms intramolecular N−H···O C hydrogen bonds, which force the polymeric chain into distorted conformations including a number of gauche bonds, whereas nylon 4 crystallizes in the fully extended all-trans structure (α form) that is stabilized by intermolecular N−H···O C hydrogen bonds
Nylon 6 is produced by ring-opening polymerization of εcaprolactam,[1] and its monomeric unit includes six carbon atoms originating from the starting material, benzene, phenol, cyclohexane, or 1-cyclohexanol
Summary
In order to suppress global warming, we are increasingly required to replace chemical production based on fossil resources with manufacture from carbon-neutral feedstock. Nylon 6 is produced by ring-opening polymerization of εcaprolactam,[1] and its monomeric unit includes six carbon atoms originating from the starting material, benzene, phenol, cyclohexane, or 1-cyclohexanol. If the carbon sources were produced from plants, nylon 6 would become a carbon-neutral material. Nylon 4 is produced from 2-pyrrolidone, which has recently come to be prepared by fermentation of biomass using Escherichia coli from biobased γ-glutamic acid via γ-aminobutyric acid;[4] nylon 4 can be considered to be biobased and carbon-neutral. It was found that nylon 4 is hydrolyzed to γ-aminobutyric acid by Pseudomonas sp. ND-11 widely inhabiting activated sludge and decomposed into CO2, H2O, and NO3−.5−10 Besides, this polyamide is degraded in vivo.[11]
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