Like thermal desorption, ultrasonic

Like thermal desorption, ultrasonic washing is a ‘green’ technique as
it does not require chemicals such as alkalis or surfactants. In the aque-
ous phase, ultrasonicwaves cause cavitation, resulting in the formation,
oscillation and finally violent collapse of bubbles responsible for various
sonophysico-chemical effects (Adewuyi, 2001; Sanderson, 2004). Due
to the powerful action of sonophysical forces in the form of microjets,
microstreaming and shock waves, a significant portion of the solid
phase is converted to the liquid phase (Mason, 2007). The desorption ef-
ficiency of ultrasonicwaves depends on several factors such as ultrason-
ic irradiation time, frequency and power, sediment type and initial
contaminant oil concentration (Li et al., 2013; Son et al., 2011). Under
the same ultrasonic power, coarse sediments desorb more oil than
fine sediments do. The high viscosity of the fine particle slurry obstructs
the ultrasound cavitations, resulting in reduced oil removal efficiency
(Abdel-Moghny et al., 2012b; Abramov et al., 2009). Oil in low content
forms monolayers on the surface of sediment particles, adhering to
the sediment with strong bonding force, whereas oil in high content
tends to form multiple layers on the sediment surface (Feng and
Aldrich, 2000; Feng et al., 2001). In a multiple oil layer system, the
outer oil layers are attached to the sediment with lower attraction
forces. As a result, it is easier to remove oil from sediment with high
oil content than sediment with low oil content (Feng and Aldrich,
2000). Increasing the ultrasonic power up to the level of cavitation
increases the rate of oil removal from oil-contaminated sediments (Na
et al., 2007; Younguk et al., 2007), whereas prolonged ultrasonication
reduces the oil removal efficiency as oil is re-adsorbed onto the sedi-
ment particles (Zhang et al., 2012). After prolonged sonication, the oil
droplet concentration in the emulsion increases, resulting in re-
adsorption of oil onto the sediment surface (Zhang et al., 2012).
Although ultrasonic desorption of oil-contaminated sediment is a
promising technique, its large-scale application needs further investiga-
tion. Previously, most researchers investigated only high-power horn-
type ultrasonic generators, which allowed vigorous mixing in a small-
volume reactor. However, large-scale reactors using vigorous mixing
with horn-type transducers would be inefficient (Son et al., 2009). To
overcome this limitation, Son et al. (2011) recently studied the remedi-
ation of diesel-contaminated sediment using plate-type ultrasonic
transducers together with mechanical mixing. However, the ultrasonic
desorption of oil-contaminated sediments has not yet been demonstrat-
ed on-site. Further research is warranted for scaling up ultrasonic
desorption technologies for large-scale field applications.