TY - JOUR
T1 - A facile energy-efficient approach to prepare super oil-sorbent thin films
AU - Saleem, Junaid
AU - Baig, Moghal Zubair Khalid
AU - Luyt, Adriaan S.
AU - Shakoor, Rana Abdul
AU - Hafeez, Ahsan
AU - Ahsan, Insharah
AU - Prahdan, Snigdhendubala
AU - Pasha, Mujahed
AU - McKay, Gordon
N1 - Publisher Copyright:
© 2022 The Author(s)
PY - 2023/5
Y1 - 2023/5
N2 - Oil spills on water surface and shoreline have caused significant water pollution, and one of the ways to deal with them is to use oil sorbents. An effective sorbent provides high oil uptake and retention values, high selectivity, super-fast uptake kinetics, and sufficient mechanical strength to ensure practical application under different conditions. In this regard, synthetic sorbents made up of graphene, carbon nanotubes, and polymers in the form of aerogels, thin films, pads, and non-woven fibers have been widely explored. However, none of them addresses all the attributes of an ideal oil sorbent. Aerogels provide extremely high uptake values, but they are so light that it is difficult for the end user to handle them. On the other hand, thin films and non-woven fibers can quickly absorb oil but suffer from low uptake capacity with low retention values. Similarly, commercial oil sorbent pads have sufficient mechanical strength, but low uptake capacity compared to aerogels. Herein, we present a super oil sorbent with a porous structure using a facile energy-efficient approach. The as-prepared sorbent comprises a porous thin film with micropores and macro-cavities, resulting in super-fast uptake kinetics and a high oil uptake value of 85 g/g. Moreover, tensile test results confirm sorbent's effectiveness in spill response. Lastly, our unique design does not involve expensive hydrophobic functionalization and thus utilizes lower embodied energy and generates lower carbon footprints.
AB - Oil spills on water surface and shoreline have caused significant water pollution, and one of the ways to deal with them is to use oil sorbents. An effective sorbent provides high oil uptake and retention values, high selectivity, super-fast uptake kinetics, and sufficient mechanical strength to ensure practical application under different conditions. In this regard, synthetic sorbents made up of graphene, carbon nanotubes, and polymers in the form of aerogels, thin films, pads, and non-woven fibers have been widely explored. However, none of them addresses all the attributes of an ideal oil sorbent. Aerogels provide extremely high uptake values, but they are so light that it is difficult for the end user to handle them. On the other hand, thin films and non-woven fibers can quickly absorb oil but suffer from low uptake capacity with low retention values. Similarly, commercial oil sorbent pads have sufficient mechanical strength, but low uptake capacity compared to aerogels. Herein, we present a super oil sorbent with a porous structure using a facile energy-efficient approach. The as-prepared sorbent comprises a porous thin film with micropores and macro-cavities, resulting in super-fast uptake kinetics and a high oil uptake value of 85 g/g. Moreover, tensile test results confirm sorbent's effectiveness in spill response. Lastly, our unique design does not involve expensive hydrophobic functionalization and thus utilizes lower embodied energy and generates lower carbon footprints.
KW - Oil spill
KW - Porous
KW - Saturation
KW - Selectivity
KW - Super sorbent
KW - Thin film
UR - http://www.scopus.com/inward/record.url?scp=85145347592&partnerID=8YFLogxK
U2 - 10.1016/j.egyr.2022.12.098
DO - 10.1016/j.egyr.2022.12.098
M3 - Article
AN - SCOPUS:85145347592
SN - 2352-4847
VL - 9
SP - 40
EP - 45
JO - Energy Reports
JF - Energy Reports
ER -