posted on 2014-11-26, 00:00authored bySijia Wang, Ning Wu
Colloidal
particles have been used extensively for stabilizing
oil–water interfaces in petroleum, food, and cosmetics industries.
They have also demonstrated promising potential in the encapsulation
and delivery of drugs. Our work is motivated by challenging applications
that require protecting and transporting active agents across the
water–oil interfaces, such as delivering catalysts to underground
oil phase through water flooding for in situ cracking of crude oil.
In this Research Article, we successfully design, synthesize, and
test a unique type of bicompartmental targeting vehicle that encapsulates
catalytic molecules, finds and accumulates at oil–water interface,
releases the catalysts toward the oil phase, and performs hydrogenation
reaction of unsaturated oil. This vehicle is based on colloidal dimers
that possess structural anisotropy between two compartments. We encapsulate
active species, such as fluorescent dye and catalytic molecules in
one lobe which consists of un-cross-linked polymers, while the other
polymeric lobe is highly cross-linked. Although dimers are dispersible
in water initially, the un-cross-linked lobe swells significantly
upon contact with a trace amount of oil in aqueous phase. The dimers
then become amphiphilic, migrate toward, and accumulate at the oil–water
interface. As the un-cross-linked lobe swells and eventually dissolves
in oil, the encapsulated catalysts are fully released. We also show
that hydrogenation of unsaturated oil can be performed subsequently
with high conversion efficiency. By further creating the interfacial
anisotropy on the dimers, we can reduce the catalyst release time
from hundred hours to 30 min. Our work demonstrates a new concept
in making colloidal emulsifiers and phase-transfer vehicles that are
important for encapsulation and sequential release of small molecules
across two different phases.