Many workers have shown that, via s

Many workers have shown that, via selective heating of the
water, microwave heating is able to enhance the separation of
water-in-oil emulsions. Fortuny et al. [4] report coalescence of
water droplets during microwave heating, and attribute this to
the reduction of the interfacial tension of the emulsion. Fang
et al. [5] report similar findings, using zeta potential to characterise
their emulsions. They showed a reduction in the zeta potential of
an oil–water emulsion after microwave treatment, and attribute
this to the ‘microwave induced molecular rotation neutralizing
the zeta potential of emulsified oil droplets’. Xia et al. [6,7] studied
conventional and microwave assisted demulsification, and they too
suggest a reduction in zeta potential due to microwave heating.
They also report that higher temperatures were achieved in their
microwave demulsification experiments compared to those carried
out using conventional heating. Ferreira et al. [8] also compared
conventional and microwave heating, and looked at the effects of
aging, demulsifier dosage and addition time. They showed that
microwave-heated emulsions separated faster than conventionally-
heated emulsions that were heated to the same average bulk
temperature. Fang and Lai [9] carried out batch microwave demulsification
experiments using 50/50 and 70/30 oil/water emulsions
made with motor oil, and Tan et al. [10] report the use of chemical
demulsifiers along with batch microwave heating. Lemos et al. [11]
and Guzmán-Lucero et al. [12] investigated the addition of ionic
liquids (IL) in conjunction with microwave treatment. Fortuny
et al. [13] proposed a promising new method for measuring salinity
in crude oils that involved a microwave demulsification step
and Binner et al. [14] evaluated a continuous flow system to assess
the impact of industrial processing conditions on microwave
enhanced emulsion separation.