posted on 2013-02-13, 00:00authored byDa Deng, Daniel P. Prendergast, John MacFarlane, Roberto Bagatin, Francesco Stellacci, Philip M. Gschwend
Widespread use of petrochemicals often leads to accidental
releases in aquatic environments, occasionally with disastrous results.
We have developed a hydrophobic and oleophilic mesh that separates
oil from water continuously in situ via capillary action, providing
a means of recovering spilt oil from surface waters. Steel mesh is
dip-coated in a xylene solution of low-density polyethylene, creating
a hydrophobic surface with tunable roughness and opening size. The
hydrophobic mesh allows oil to pass through the openings while preventing
the concomitant passage of water. A bench-top prototype demonstrated
the efficacy of such an oil recovery device and allowed us to quantify
the factors governing the ability of the mesh to separate oil and
water. Preliminary data analysis suggested that the oleophilic openings
behave somewhat like capillary tubes: the oil flux is inversely proportional
to oil viscosity, and directly proportional to the size of the mesh
openings. An unpinned meniscus model was found to predict the water
intrusion pressure successfully, which increased as the opening size
decreased. The trade-off between water intrusion and oil flow rate
suggests an optimal pore size for given oil properties and sea conditions.