Gerber I, Oubenali M, Bacsa R et al (2011) Theoretical and experimental studies on the carbon-nanotube surface oxidation by nitric acid: interplay between functionalization and vacancy enlargement. Ge J, Zhao HY, Zhu HW et al (2016) Advanced sorbents for oil-spill cleanup: recent advances and future perspectives. J Colloid Interface Sci 305:7–16Įtkin DS, Nedwed TJ (2021) Effectiveness of mechanical recovery for large offshore oil spills. Energy 260:124993ĭíaz E, Ordóñez S, Vega A (2007) Adsorption of volatile organic compounds onto carbon nanotubes, carbon nanofibers, and high-surface-area graphites. ĭeng Y, Ma X, Zhang P, Cai Y (2022) Multi-step ahead forecasting of daily urban gas load in Chengdu using a Tanimoto kernel-based NAR model and Whale optimization. Ĭheng H, Gu B, Pennefather MP et al (2017) Cotton aerogels and cotton-cellulose aerogels from environmental waste for oil spillage cleanup. Ĭhaudhary S, Dora DTK, Reddy DS, Porwal SK (2022) Sustainable non-cytotoxic ultra-light aerogel derived from waste tissue paper as an effective hemostatic agent. Ĭhatterjee S, Ke WT, Liao YC (2020) Elastic nanocellulose/graphene aerogel with excellent shape retention and oil absorption selectivity. pp 83–87īidgoli H, Khodadadi AA, Mortazavi Y (2019) A hydrophobic/oleophilic chitosan-based sorbent: toward an effective oil spill remediation technology. In: 24th International Mining Congress and Exhibition of Turkey, Antalya, Turkey. Energy Sour Part B Econ Plan Policy 11:212–219Īydin G, Kaya S, Karakurt I (2015) Modeling of coal consumption in Turkey: An application of trend analysis. Īydin G, Jang H, Topal E (2016) Energy consumption modeling using artificial neural networks: The case of the world’s highest consumers. Īdebajo MO, Frost RL, Kloprogge JT et al (2003) Porous materials for oil spill cleanup: a review of synthesis and absorbing properties. Chemosphere 260:127586Ībjameh R, Moradi O, Amani J (2014) The study of synthesis and functionalized single-walled carbon nanotubes with amide group. Environ Technol Innov 18:100598Ībidli A, Huang Y, Park CB (2020b) In situ oils/organic solvents cleanup and recovery using advanced oil-water separation system. Thus, the outstanding characteristics and hydrophobicity of the synthesized aerogel in this work establish itself as a capable adsorbent for oil spill cleaning.Ībidli A, Huang Y, Cherukupally P et al (2020a) Novel separator skimmer for oil spill cleanup and oily wastewater treatment: From conceptual system design to the first pilot-scale prototype development. Furthermore, the aerogel can be regenerated by the treatment with acetone and sustain its oil sorption capacity up to 5 regeneration cycles. The oil sorption kinetics revealed that the oil sorption on to the O-MWCNT-silica aerogel followed the pseudo-second-order kinetics with the particular correlation coefficients ( R 2) of 0.9898. The sorption capacity of the aerogel investigated using motor oil projected an oil sorption capacity of about 13.72, 16.70, and 19.48 g/g at 25, 30, and 40 ☌, respectively. Moreover, the synthesized aerogel exhibited hydrophicity, with a water contact angle of 136.2°. The density of the O-MWCNT-silica aerogel was 0.02 g/cc with a porosity of 87%, confirming its ultra-light and high porosity nature. The developed aerogel possesses high specific surface area of 795 m 2/g evaluated from Brunauer–Emmett–Teller (BET) model, with a pore size of 11.2 nm. The synthesized aerogel was hydrophobisized through surface modification with trimethylsilyl chloride for its application as an oil spill cleaning agent. In the present work, bamboo-shaped Oxidized Multi-walled Carbon Nanotubes (O-MWCNT) synthesized through catalytic decomposition of natural gas were reinforced in a silica matrix to achieve a robust O-MWCNT-silica aerogel.
0 Comments
Leave a Reply. |
AuthorWrite something about yourself. No need to be fancy, just an overview. ArchivesCategories |