The diphenylalanine peptide self-assembles
to form nanotubular
structures of remarkable mechanical, piezolelectrical, electrical,
and optical properties. The tubes are unexpectedly stiff, with reported
Young’s moduli of 19–27 GPa that were extracted using
two independent techniques. Yet the physical basis for the remarkable
rigidity is not fully understood. Here, we calculate the Young’s
modulus for bulk diphenylalanine peptide from first principles, using
density functional theory with dispersive corrections. The calculation
demonstrates that at least half of the stiffness of the material is
the result of dispersive interactions. We further quantify the nature
of various inter- and intramolecular interactions. We reveal that
despite the porous nature of the lattice, there is an array of rigid
nanotube backbones with interpenetrating “zipper-like”
aromatic interlocks that result in stiffness and robustness. This
presents a general strategy for the analysis of bioinspired functional
materials and may pave the way for rational design of bionanomaterials.