Membrane fouling by organic, inorganic and biological materials is a significant cause of the increased operational
costs in the membrane separation processes such as reverse osmosis, nanofiltration, ultrafiltration and
microfiltration. To better understand the fouling mechanism and increase the membrane performance via optimizing
membrane structure, elucidation of the physicochemical interactions between membranes and foulants
is essential. Atomic force microscopy (AFM) has been proved to be a powerful method to qualitatively characterize
the interaction force between the tip and the substrate. In this paper, the AFM tips were modified to bear
five representative organic end-groups: benzyl, hexyl, propionic acid, ethylamine hydrochloride, sodium propyl
sulfonate, which are commonly found in organic foulants. The adhesion force between the modified AFM tip and
the reverse osmosis membrane was measured carefully to understand the potential fouling tendency of each
category function group on the membrane. The results showed the average interaction force between the tip
modified by -(CH2)3-SO3Na group and membrane is 13.80 nN, which is as twice as the force between membrane
and the unmodified tip. The results also showed that the tips modified by -(CH2)2-COOH group and -(CH2)3-
SO3Na group, have stronger interaction force with the membrane surface than the tips modified by three other
end-groups, which indicated these two kinds of organic compounds are easier to deposit on the membrane
surface and cause membrane fouling. It should be possible to use the method developed in this paper to predict
the organic fouling on other types of membranes beyond reverse osmosis membrane.