Microstructure of Crystallizable alpha-Olefin Molecular Bottlebrushes: Isotactic and Atactic Poly(1-octadecene)
CR Lopez-Barron and AH Tsou and JM Younker and AI Norman and JJ Schaefer and JR Hagadorn and JA Throckmorton, MACROMOLECULES, 51, 872-883 (2018).
DOI: 10.1021/acs.macromol.7b02524
Isotactic and atactic poly(1-octadecene) (iPOD and aPOD) have been synthesized by organometallic coordinative insertion polymerization of 1-octadecene. Analyzing X-ray and neutron scattering data of POD melts identifies their bottlebrush structures as flexible rods where the rod length is the extended backbone length and rod radius is the side chain coil dimension. Upon cooling, both iPOD and aPOD melts crystallize by fully extending their coiled side chains to form orthorhombic alkane crystals in iPOD and nematically ordered rotator alkane crystals in aPOD, as determined by X-ray scattering and Raman spectroscopy. Molecular dynamics simulations of isotactic and atactic 48-mers of 1-octadecene were applied to define and verify melt and crystalline structures and scattering peak assignments, respectively. Modeling suggests that side chains of both crystallized isotactic and atactic PODs align at 70 degrees and 160 degrees to the 4/1 spiral backbone of equal probability, at an average of 115 degrees, and POD chains pack in an antiparallel pattern. Large wheat-sheaf structural assembly of fibril bundles can be observed in aPOD, which render high opacity to these samples. Each of those fibrils is made of several bottlebrush molecules packed into a hexagonal lattice. Faster crystallization observed in iPODs hinders the formation of large crystallites, which results in translucent samples.
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