posted on 2023-08-08, 01:33authored byDilara Hatinoglu, Junseok Lee, John Fortner, Onur Apul
Wastewater treatment plants are critical for environmental
pollution
control. The role that they play in protecting the environment and
public health is unquestionable; however, they produce massive quantities
of excess sludge as a byproduct. One pragmatic approach to utilizing
excess sludge is generating methane via anaerobic digestion. For this,
a prehydrolysis step can significantly improve digestion by increasing
biogas quality and quantity while decreasing final sludge volumes.
One of the many prehydrolysis approaches is to deliver heat into sludge
via microwave irradiation. Microwave-absorbing additives can be used
to further enhance thermal degradation processes. However, the implications
of such an approach include potential release of said additive materials
into the environment via digested sludge. In this perspective, we
present and discuss the potential of superparamagnetic iron oxide
nanoparticles (SPIONs) as recoverable, hyperreactive microwave absorbers
for sludge prehydrolysis. Due to their size and characteristics, SPIONs
pack spin electrons within a single domain that can respond to the
magnetic field without remanence magnetism. SPIONs have properties
of both paramagnetic and ferromagnetic materials with little to no
magnetic hysteresis, which can enable their rapid recovery from slurries,
even in complicated reactor installations. Further, SPIONs are excellent
microwave absorbers, which result in high local heat gradients. This
perspective introduces the vision that SPION properties can be tuned
for desirable dielectric heating and magnetic responses while maintaining
material integrity to accomplish repeated use for microwave-enhanced
pretreatment.