Structural properties of aqueous grown polydopamine thin films determined by neutron reflectometry

In this work, neutron reflectometry (NR) studies of the bio-mimetic polymer, polydopamine (PDA), deposited from differing initial concentrations of precursor material dopamine hydrochloride for a range of polymeriza-tion times, is reported. PDA can form a complex and highly versatile polymer film, with many structure studies having been performed previously, but a comprehensive structural determination of PDA by NR is lacking in the literature. It was found that simple box models were incapable of fully explaining the observed data, necessitating the use of a composite model consisting of the weighted average of both the 1 and 2 box models to fully capture the heterogeneous nature of the PDA film structure. Confocal laser scanning microscopy (CLSM) and atomic force microscopy (AFM) were performed to capture the surface structure and relative mechanical difference between the separate domains of the PDA. The CLSM results provide evidence that the PDA domains are larger than the coherent scattering length of a neutron used in these measurements, 10 mu m, supporting the need for a composite model. The AFM measurements show complex structure below the coherence length provide physical justification for the two box model. It was determined that film structure and quality are both heavily impacted by the initial concentration of dopamine hydrochloride and the polymerization time, giving confidence to the highly customizable nature of PDA as an adhesion promoting interface treatment in composite systems, such as plastic bonded explosives (PBX).

Automated summary

This study reports neutron reflectometry (NR) studies of bio-mimetic polymer polydopamine (PDA) deposited from differing initial concentrations of precursor material dopamine hydrochloride. Confocal laser scanning microscopy (CLSM) and atomic force microscopy (AFM) were performed to understand the surface structure and mechanical differences of PDA. The results show that film structure and quality are heavily impacted by the initial concentration of dopamine hydrochloride and the polymerization time, indicating the highly customizable nature of PDA.