posted on 2015-07-07, 00:00authored byZhitong Yao, Liuqin Ge, Wenye Yang, Meisheng Xia, Xiaosheng Ji, Meiqing Jin, Junhong Tang, Jürgen Dienstmaier
An
improved understanding of a filler’s surface properties
is important for determining the most effective polymer reinforcement
fillers. In this work, the surface characteristics of two biofillers,
namely, clam shell modified by hydrochloric acid (AMF) and furfural
(FMF), were investigated using inverse gas chromatography (IGC). The
IGC results showed that the dispersive surface energy (γSD) contributed the
major part to the total surface energy for the biofillers. The values
changed as a function of surface coverages, meaning that both samples
were energetically fairly heterogeneous. The γSD calculated with the Dorris–Gray
method was larger than that calculated with the Schultz method, with
a γS,Dorris–GrayD/γS,SchultzD ratio of 1.10. Compared to AMF, FMF
possessed higher γSD value; however, this difference was compensated by specific
(acid–base) surface energy (γSAB). Both samples predominantly interacted
with ethanol and acetonitrile, implying an amphoteric nature of the
material surfaces. Gutmann acid and base number profiles indicated
that the surfaces of both samples were more basic in nature. The FMF
showed a lower total work of cohesion (WCohtotal) value compared to the AMF, which could lead to
an increase in composite performance.