Fiber reinforced polymer composites (FRPs) have been extensively utilized in loadbearing structures. Their ease of forming and
their superior in-plane mechanical properties have made them a viable replacement for conventional metallic structural materials.
However, FRPs are prone to several drawback such as weak interlaminar fracture toughness, poor out-of-plane properties,
vulnerability to viscoplastic deformation and poor impact energy absorption. To overcome these drawbacks, several remedies
were carried out to enhance the fiber/matrix interfaces via chemical treatments or utilizing stiffer nanomaterials at the interface.
This presentation will elucidate fundamental processes for developing hybrid, multifunctional composites based on surface
grown carbon nanotubes (CNTs) and/or metal organic frameworks (MOFs) on continuous carbon fibers. This presentation will
outline the development of a novel low temperature synthesis technique, graphitic structures by design (GSD), to grow CNTs on
carbon fiber. The novelty of the GSD technique resides in its ability to pattern-grow CNTs in different morphologies to achieve
optimal mechanical performance. Mechanical testing revealed that the hybrid composites possess superior impact, vibration,
interlaminar shear strength, fracture toughness and fatigue resistance compared to classical FRPs. This investigation also
corroborates a novel methodology for developing hybrid reinforcements that comprises carbon fibers and MOFs. The growth of
MOFs is scalable, non-destructive to the fibers, and easily tailorable to control the porous morphologies of the MOFs at the interface.
Furthermore, the study demonstrates the feasibility of utilizing the MOFs as a catalyst to grow carbon nanotubes (CNTs)
on the carbon fibers. Several improvements emanated from the MOFs placement on the interface including improving the
strength, enhancing the damping parameter, the glass transition temperature of the composite and alleviating the shear lap joint
strength.
Since the both GSD technique and MOFs synthesis are readily transferable to chopped fibers, this presentation also will elucidate
the ongoing feasibility study for utilizing hybrid reinforcements for 3D printing of epoxy-based composites and for processing
them using Joule heating out- of- an autoclave.