Connection between the vibrational dynamics and the cross-linking properties in cyclodextrins-based polymers

The vibrational dynamics of a new class of cross-linked polymers obtained from both native and modified cyclodextrin,
referred to as cyclodextrin nanosponges, is here investigated. The main purpose is to spot the structure of these materials
at molecular level unlikely to be characterized by diffraction methods due to the low or null degree of crystallinity. The
analysis of the spectral features of the vibrational bands observed between 1650 and 1800 cm1 in both Raman and infrared
spectra, and assigned to the carbonyl stretching modes of the polymeric network, is performed by using band deconvolution
procedures. At the same time, a detailed inspection of the low-wavenumber vibrational dynamics of these polymers is carried
out, focusing on the modifications occurring on the so-called boson peak.
The simultaneous analysis of different wavenumber ranges in Raman and infrared spectra of cyclodextrin nanosponges
allows us to develop a reliable strategy for exploring both the cross-linking degree and the elastic properties of these
innovative materials. The overall results give a complete characterization of the structural and dynamical properties of
the system, in turn strictly connected to the entrapment/transport ability of these polymeric matrices.