Conspectus
Various methods have been developed in surface
chemistry to control
interface properties of a solid material. A selection rule among surface
chemistries is compatibility between a surface functionalization tool
and a target material. For example, alkanethiol deposition on noble
metal surfaces, widely known as the formation of a self-assembled
monolayer (SAM), cannot be performed on oxide material surfaces. One
must choose organosilane molecules to functionalize oxide surfaces.
Thus, the surface chemistry strictly depends on the properties of
the surface. Polydopamine coating is now generally accepted as the
first toolbox for functionalization of virtually any material surface.
Layer-by-layer (LbL) assembly is a widely used method to modify properties
of versatile surfaces, including organic materials, metal oxides,
and noble metals, along with polydopamine coating. On flat solid substrates,
the two chemistries of polydopamine coating and LbL assembly provide
similar levels of surface modifications. However, there are additional
distinct features in polydopamine. First, polydopamine coating is
effective for two- or three-dimensional porous materials such as metal–organic
frameworks (MOFs), synthetic polyolefin membranes, and others because
small-sized dopamine (MW = 153.18 u) and its oxidized oligomers are
readily attached onto narrow-spaced surfaces without exhibiting steric
hindrance. In contrast, polymers used in LbL assembly are slow in
diffusion because of steric hindrance due to their high molecular
weight. Second, it is applicable to structurally nonflat surfaces
showing special wettability such as superhydrophobicity or superoleophobicity.
Third, a nonconducting, insulating polydopamine layer can be converted
to be a conducting layer by pyrolysis. The product after pyrolysis
is a N-doped graphene-like material that is useful for graphene or
carbon nanotube-containing composites. Fourth, it is a suitable method
for engineering the surface properties of various composite materials.
The surface properties of participating components in composite materials
can be unified by polydopamine coating with a simple one-step process.
Fifth, a polydopamine layer exhibits intrinsic chemical reactivity
by the presence of catecholquinone moieties and catechol radical species
on surfaces. Nucleophiles such as amine and thiolate spontaneously
react with the functionalized layer.
Applications of polydopamine
coating are exponentially growing
and include cell culture/patterning, microfluidics, antimicrobial
surfaces, tissue engineering, drug delivery systems, photothermal
therapy, immobilization of photocatalysts, Li-ion battery membranes,
Li–sulfur battery cathode materials, oil/water separation,
water detoxification, organocatalysts, membrane separation technologies,
carbonization, and others. In this Account, we describe various polydopamine
coating methods and then introduce a number of chemical derivatives
of dopamine that will open further development of material-independent
surface chemistry.
