Conformational
Dynamics of Surfactant in a Mesolamellar
Composite Studied by Local Field NMR Spectroscopy
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Abstract
Ordered mesostructured materials
possess unique surface, structural,
and bulk properties that lead to important practical applications.
Mesostructured organic–inorganic composites are also of broad
interest for fundamental studies of confinement effects and surface
interaction on structural and dynamic properties of organic molecules.
In the present study, solid state dipolar <sup>13</sup>C–<sup>1</sup>H NMR spectroscopy is applied to quantitatively characterize
the conformational dynamics of a surfactant in a mesolamellar composite.
By applying dipolar recoupling and separated local field spectroscopy
techniques, the motion of surfactant molecules was studied in a wide
range of mobilities from an essentially immobilized rigid state to
a highly flexible and anistropically tumbling state. From the analysis
of the measured heteronuclear dipolar couplings, the orientational
order parameters of C–H bonds along the surfactant chain were
determined. The study shows that in surfactant bilayers in AlPO layered
structure at room temperature the highly ordered chains in all-trans
conformation undergo fast rotation about the molecular axis. In a
higher temperature phase, the order parameter is gradually decreasing
toward the chain end due to conformational transitions; however, the
dynamics of the segment in the vicinity of the headgroup is only slightly
affected. The conformational dynamics in the surfactant bilayers confined
between solid inorganic sheets is also compared to that in fluid bilayers
in an aqueous lamellar phase