Growth of rGO nanostructures via facile wick and oil flame synthesis for environmental remediation
* 본 문서는 배포용으로 복사 및 편집이 불가합니다.
서지정보
ㆍ발행기관 : 한국탄소학회
ㆍ수록지정보 : Carbon letters / 31권 / 4호
ㆍ저자명 : G. S. Lekshmi, R. Tamilselvi, Karthika Prasad, Olha Bazaka, Igor Levchenko, Kateryna Bazaka, Mandhakini Mohandas
ㆍ저자명 : G. S. Lekshmi, R. Tamilselvi, Karthika Prasad, Olha Bazaka, Igor Levchenko, Kateryna Bazaka, Mandhakini Mohandas
목차
Abstract1 Introduction
2 Experimental details
2.1 Materials and processes
2.2 Adsorption kinetics of oils on RGO
3 Results and discussion
3.1 XRD, raman and FTIR characterization of As-Prepared RGO
3.2 SEM, AFM and EDX characterization of As-prepared RGO
3.3 Contact angle and absorption measurements
3.4 FTIR spectra
3.5 Analysis of absorption kinetics
3.6 Mechanism of RGO growth
3.7 Effect of temperature and thermodynamic parameters
4 Conclusion
References
영어 초록
Oil spills into ocean or coastal waters can result in significant damage to the environment via pollution of aquatic ecosystems. Absorbents based on reduced graphene oxide (rGO) foams have the capacity to remove minor or major oil spills. However, conventional chemical synthesis of rGO often uses petrochemical precursors, potentially harmful chemicals, and requires special processing conditions that are expensive to maintain. In this work, an alternative cost-effective and environmentally friendly approach suitable for large-scale production of high-quality rGO directly from used cooking sunflower oil is discussed. Thus, produced flaky graphene structures are effective in absorbing used commercial sunflower oil and engine oil, via monolayer physisorption in the case of used sunflower and engine oils facilitated by van der Waals forces, π–π stacking and hydrophobic interactions, π-cation ( H+) stacking and radical scavenging activities. From adsorption kinetic models, first-order kinetics provides a better fit for used sunflower oil adsorption (R2 = 0.9919) and second-order kinetics provides a better fit for engine oil adsorption (R2 = 0.9823). From intra-particle diffusion model, R2 for USO is 0.9788 and EO is 0.9851, which indicates that both used sunflower and engine oils adsorption processes follow an intra-particle diffusion mechanism. This study confirms that waste-derived rGO could be used for environmental remediation.참고 자료
없음"Carbon letters"의 다른 논문
Synthesis of MoS2 nanoparticles grown on crumpled 3D gr..6페이지
Development of nitrogen‑doped carbon quantum dots as fl..9페이지
Facile tuning of carbon nanotube morphologies via resid..11페이지
Modification of the graphene oxide surface with copper ..13페이지
Activated carbon microspheres derived from hydrothermal..15페이지
Valuation of banana peel waste for producing activated ..14페이지
Camphor leaf‑derived activated carbon prepared by conve..12페이지
A simple nonenzymatic glucose sensor based on coconut s..7페이지
Valorization of spent activated carbon in glycerine deo..8페이지
Electrical percolation and fluidity of conductive recyc..14페이지