Tuning interactions at the interfaces
in carbon fiber (CF)-reinforced
polymer composites necessitates the implementation of CF surface modification
strategies that often require destructive environmentally unfriendly
chemistries. In this study, interfacial interactions in cellulose-based
composites are tailored by means of a mussel-inspired adhesive polydopamine
(PDA) coating, being inherently benign for the environment and for
the structure of CFs. The step-by-step growth of PDA was followed
by increasing treatment time leading to a hydrophilic PDA-coated surface,
presumably via surface-based polymerization mechanisms attributed
to strong π–π stacking interactions. Although PDA
deposition led to an initial increase in the interfacial shear strength
(IFSS) (5 h), it decreased at a longer reaction time (24 h), the formation
of weakly attached PDA particles on the coated surface can possibly
lie behind the latter phenomenon. Nevertheless, the mechanical properties
of the prepared short CF-reinforced composite were improved (tensile
strength increased ∼12% compared to the unmodified surface)
with decreasing IFSS owing to the particular morphological design,
resulting in longer fiber segments. Our study underlines the importance
of the morphological design at the interface and considers PDA as
a promising bioinspired material to tailor interfacial interactions.