Nanoparticles
(NPs) as part of engineered nanomaterials (ENMs)
possess outstanding properties. Thus, they are more frequently integrated
into various products resulting in high annual production quantities.
The consequence can be the unintentional release into the environment
where NPs could accumulate and pose a threat to human health. Therefore,
the strong need becomes apparent for the remediation of environmental
media. Electrospun nonwovens, which are defined here as membranes,
could efficiently remove these released NPs. In this paper, electrospun
membranes are utilized to flow filtration of metal and metal oxide
NP, such as gold, silver, copper oxide, zinc oxide, iron oxide, and
titanium dioxide. The membrane–NP interaction was analyzed
and the correlation between NP size, NP ligand, ligand concentration,
and the membrane surface functional group was investigated systematically.
Finally, a membrane combining two functional groups was designed,
which is able to adsorb up to 100% of the filtered NPs. The highest
adsorption capacity was provided by AuNPs with 0.14 mg NP/mg
membrane. To enhance their lifetime and gain sustainability, the membranes
were then regenerated three times by rinsing with low concentrated
acids. No significant efficiency loss was recorded, which allowed
reusability of the electrospun membranes. We believe that the results
shown here are of general relevance for other metals, metal oxides,
and microplastic particles as well.