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TY  - JOUR
DO  - 10.1021/acs.est.1c01251
UR  - http://dx.doi.org/10.1021/acs.est.1c01251
TI  - Recent Advances in Sulfidated Zerovalent Iron for Contaminant Transformation
T2  - Environmental Science & Technology
AU  - Garcia, Ariel Nunez
AU  - Zhang, Yanyan
AU  - Ghoshal, Subhasis
AU  - He, Feng
AU  - O’Carroll, Denis M.
PY  - 2021
DA  - 2021/06/25
PB  - American Chemical Society (ACS)
SP  - 8464-8483
IS  - 13
VL  - 55
SN  - 0013-936X
SN  - 1520-5851
N2  - 2021 marks 10 years since controlled abiotic synthesis of sulfidated nanoscale zerovalent iron (S-nZVI) for use in site remediation and water treatment emerged as an area of active research. It was then expanded to sulfidated microscale ZVI (S-mZVI) and together with S-nZVI, they are collectively referred to as S-(n)ZVI. Heightened interest in S-(n)ZVI stemmed from its significantly higher reactivity to chlorinated solvents and heavy metals. The extremely promising research outcomes during the initial period (2011–2017) led to renewed interest in (n)ZVI-based technologies for water treatment, with an explosion in new research in the last four years (2018–2021) that is building an understanding of the novel and complex role of iron sulfides in enhancing reactivity of (n)ZVI. Numerous studies have focused on exploring different S-(n)ZVI synthesis approaches, and its colloidal, surface, and reactivity (electrochemistry, contaminant selectivity, and corrosion) properties. This review provides a critical overview of the recent milestones in S-(n)ZVI technology development: (i) clear insights into the role of iron sulfides in contaminant transformation and long-term aging, (ii) impact of sulfidation methods and particle characteristics on reactivity, (iii) broader range of treatable contaminants, (iv) synthesis for complete decontamination, (v) ecotoxicity, and (vi) field implementation. In addition, this review discusses major knowledge gaps and future avenues for research opportunities.
L1  - https://sci-hub.se/downloads/2021-08-11/83/garcia2021.pdf
ER  - 

TY  - JOUR
T1  - Pore-scale simulation of nanoparticle transport and deposition in a microchannel using a Lagrangian approach
AU  - Ramezanpour, Milad
AU  - Siavashi, Majid
AU  - Raeini, Ali Q.
AU  - Blunt, Martin J.
JO  - Journal of Molecular Liquids
VL  - 355
SP  - 118948
PY  - 2022
DA  - 2022/06/01/
SN  - 0167-7322
DO  - 10.1016/j.molliq.2022.118948
UR  - https://www.sciencedirect.com/science/article/pii/S016773222200486X
KW  - Nanoparticle
KW  - Lagrangian
KW  - Van der Waals
KW  - Electrostatic
KW  - Brownian motion
KW  - Deposition
AB  - The application of nanoparticles to a fluid improves heat transfer and hydrodynamics, especially in porous media. To analyze the flow of nanoparticles and heat transfer in porous media at the pore scale, simulation in micro-scale channels of porous media is necessary. One concern is the deposition of nanoparticles to solid surfaces, which reduces the amount of material available in the bulk fluid. Also, in porous media, the nanoparticle deposition increases the surface roughness of pore surfaces, affecting the volumetric flow rate of nanofluid. Nanoparticle transport and deposition in a microchannel (as a representation of pore) are investigated numerically. The open-source library of OpenFOAM is used, and the Eulerian-Lagrangian (EL) approach is employed to simulate nanoparticles interacting with the base fluid and the surfaces of the microchannel. Integration of all forces exerted on nanoparticles, from base fluid and also microchannel’s surfaces are considered simultaneously. Brownian motion, drag, buoyancy, gravity, and Saffman lift forces are considered between nanoparticles and the base fluid. Van der Waals and electrostatic double-layer forces based on DLVO theory are considered between nanoparticles and microchannel surfaces. The deposition ratio of nanoparticles (the fraction of nanoparticles that deposit on the solid surface) is analyzed by the variation of nanoparticle diameter, fluid velocity, temperature, surface potentials, and double-layer thickness. It is assumed that the nanofluid is dilute, and the collisions between the nanoparticles are neglected. The results of nanoparticle deposition ratio are validated through comparison with available data in the literature. It has been shown that the nanoparticle deposition ratio decreases from 0.98 to 0.4 when the nanoparticle diameter increases from 30 to 150 nm. The effect of Van der Waals force on the enhancement of nanoparticle deposition ratio is about 1.6 %. Next, the deposition of nanoparticles is studied for different Reynolds number values, surface potential, nanoparticle radius, and double-layer thickness. Brownian motion dominates the behavior; increasing temperature and decreasing nanoparticle diameter will increase nanoparticle deposition. The magnitude of the nanoparticle and surface potentials and the double layer thickness are the two essential parameters that control the electrostatic double-layer force; its effect on deposition is also investigated. It has been concluded that the rise of the surface potential value decreases the deposition ratio.
TI  - Pore-scale simulation of nanoparticle transport and deposition in a microchannel using a Lagrangian approach
T2  - Journal of Molecular Liquids
PB  - Elsevier BV
L1  - file://C:\Users\Administrator\Downloads\文献ris\Pore-scale simulation of nanoparticle transport and deposition in a microchannel using a Lagrangian approach.pdf
ER  - 

TI  - Even Incorporation of Nitrogen into Fe<sup>0</sup> Nanoparticles as Crystalline Fe<sub>4</sub>N for Efficient and Selective Trichloroethylene Degradation
T2  - Environmental Science &amp; Technology