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1. Role of Oxygen Functionalities in Graphene Oxide Architectural Laminate Subnanometer Spacing and Water Transport

Author

Amadei, Carlo Alberto, Montessori, Andrea, Kadow, Julian P., Succi, Sauro, and Vecitis, Chad D.

Subjects
Physics - Fluid Dynamics
Abstract

Active research in nanotechnology contemplates the use of nanomaterials for engineering applications. However, a primary challenge is understanding the effects of nanomaterial properties on industrial device performance and translating unique nanoscale properties to the macroscale. One emerging example is graphene oxide (GO) membranes for separation processes. Thus, here we investigate how individual GO properties can impact layered GO characteristics and water permeability. GO chemistry and morphology were controlled with easy-to-implement photo-reduction and sonication techniques and were quantitatively correlated offering a valuable tool to speed up the characterization process. For example, one could perform chemical analysis and concurrently obtain morphology information or vice versa. Chemical GO modification allows for fine control of GO oxidation state and GO laminate nanoarchitecture enabling controlled synthesis of a GO architectural laminate (GOAL). The GOAL can be considered as the selective layer of the membrane created by interconnected sub-nanometer channels, characterized by a length and a height (i.e., GO spacing), through which water molecules permeate. Water permeability was measured for eight GOAL characterized by different GO chemistry and morphology, and indicate that GO nanochannel height dictates water transport. The simulations indicate a no-slip Darcy-like water transport regime inside the GOAL due to the presence of basal oxygen functionalities. The experimental and simulation evidence presented in this letter help create a clearer picture of water transport in GO and can be used to rationally design more effective and efficient GO membranes., Comment: 25 pages

Published
2022
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4. Electro‐Conductive Ti3C2 MXene Multilayered Membranes: Dye Removal and Antifouling Performance.

Author

Zandi, Zahra, Rastgar, Masoud, Mohseni, Mojtaba, Firouzjaei, Mostafa Dadashi, Dilokekunakul, Waralee, Anasori, Babak, Vecitis, Chad D., Keller, Robert, Wessling, Matthias, Elliott, Mark, Rahimpour, Ahmad, and Sadrzadeh, Mohtada

Subjects
SURFACE energy, CARBOXYMETHYLCELLULOSE, SURFACE analysis, WASTEWATER treatment, ELECTRIC conductivity
Abstract

This work describes the fabrication of a novel electroconductive membrane made of Ti3C2Tx (MXene) nanosheet coating through a one‐step pressure‐assisted technique. Ti3C2‐MXene is firmly attached over a polyamide–imide (PAI) microfilter by employing a binder composed of carboxymethyl cellulose (CMC)/glutaraldehyde (GA). Through coating a proper amount of multilayer Ti3C2‐MXene, the electrical conductivity of 174 ± 0.16 S m−1 is achieved. The rejection rates of reactive red 120 (RR120), reactive black (RB), and methyl orange (MO) by the pristine PAI membrane are 45.2%, 40.81%, and 33.65%, respectively. However, rejection rates significantly improve with the Ti3C2 MXene coating to over 99.71%, 97.95%, and 68.91% for RR120, RB, and MO. Applying a 4 V cathodic potential resulted in a flux recovery ratio (FRR) of 99.83% and a flux decline rate (FDR) of less than 1% during humic acid (HA) filtration. Without applying voltage, the MXene‐coated membrane shows an FRR and FDR of 92.51% and 45.56%, respectively. Surface energy analysis reveals strong repulsive interactions between foulants and the membrane surface. Moreover, the surface free energy indicates that foulants such as sodium alginate (SA) and bovine serum albumin (BSA) exhibit stronger adhesion to the membrane than HA, consistent with the fouling experiment results. [ABSTRACT FROM AUTHOR]

Published
2024
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10. Removal of Emerging Contaminants from Water Using Novel Electroconductive Membranes in a Hybrid Membrane Distillation and Electro-Fenton Process

Author

Omi, Farah Rahman, primary, Rastgar, Masoud, additional, Mohseni, Mojtaba, additional, Singh, Upasana, additional, Dilokekunakul, Waralee, additional, Keller, Robert, additional, Wishart, David A., additional, Wessling, Matthias, additional, Vecitis, Chad Davis, additional, and Sadrzadeh, Mohtada, additional

Published
2024
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21. Nitrifying Microorganisms Linked to Biotransformation of Perfluoroalkyl Sulfonamido Precursors from Legacy Aqueous Film-Forming Foams

Author

Ruyle, Bridger J., primary, Schultes, Lara, additional, Akob, Denise M., additional, Harris, Cassandra R., additional, Lorah, Michelle M., additional, Vojta, Simon, additional, Becanova, Jitka, additional, McCann, Shelley, additional, Pickard, Heidi M., additional, Pearson, Ann, additional, Lohmann, Rainer, additional, Vecitis, Chad D., additional, and Sunderland, Elsie M., additional

Published
2023
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22. Nitrifying Microorganisms Linked to Biotransformation of Perfluoroalkyl Sulfonamido Precursors from Legacy Aqueous Film-Forming Foams

Author

Ruyle, Bridger J., Schultes, Lara, Akob, Denise A., Harris, Cassandra R., Lorah, Michelle M., Votja, Simon, Becanova, Jitka, McCann, Shelley, Pickard, Heidi M., Pearson, Ann, Lohmann, Rainer, Vecitis, Chad D., Sunderland, Elsie M., Ruyle, Bridger J., Schultes, Lara, Akob, Denise A., Harris, Cassandra R., Lorah, Michelle M., Votja, Simon, Becanova, Jitka, McCann, Shelley, Pickard, Heidi M., Pearson, Ann, Lohmann, Rainer, Vecitis, Chad D., and Sunderland, Elsie M.

Abstract

Drinking water supplies across the United States have been contaminated by firefighting and fire-training activities that use aqueous film-forming foams (AFFF) containing per- and polyfluoroalkyl substances (PFAS). Much of the AFFF is manufactured using electrochemical fluorination by 3M. Precursors with six perfluorinated carbons (C6) and non-fluorinated amine substituents make up approximately one-third of the PFAS in 3M AFFF. C6 precursors can be transformed through nitrification (microbial oxidation) of amine moieties into perfluorohexane sulfonate (PFHxS), a compound of regulatory concern. Here, we report biotransformation of the most abundant C6 sulfonamido precursors in 3M AFFF with available commercial standards (FHxSA, PFHxSAm, and PFHxSAmS) in microcosms representative of the groundwater/surface water boundary. Results show rapid (<1 day) biosorption to living cells by precursors but slow biotransformation into PFHxS (1–100 pM day–1). The transformation pathway includes one or two nitrification steps and is supported by the detection of key intermediates using high-resolution mass spectrometry. Increasing nitrate concentrations and total abundance of nitrifying taxa occur in parallel with precursor biotransformation. Together, these data provide multiple lines of evidence supporting microbially limited biotransformation of C6 sulfonamido precursors involving ammonia-oxidizing archaea (Nitrososphaeria) and nitrite-oxidizing bacteria (Nitrospina). Further elucidation of interrelationships between precursor biotransformation and nitrogen cycling in ecosystems would help inform site remediation efforts.

Published
2023

24. O2-Independent H2O2Production via Water–Polymer Contact Electrification

Author

Wang, Yanfeng, Wei, Peiyun, Shen, Zihan, Wang, Chao, Ding, Jie, Zhang, Wenkai, Jin, Xin, Vecitis, Chad D., and Gao, Guandao

Abstract

Hydrogen peroxide (H2O2), as a critical green chemical, has received immense attention in energy and environmental fields. The ability to produce H2O2in earth-abundant water without relying on low solubility oxygen would be a sustainable and potentially economic process, applicable even to anaerobic microenvironments, such as groundwater treatment. However, the direct water to H2O2process is currently hindered by low selectivity and low production rates. Herein, we report that poly(tetrafluoroethylene) (PTFE), a commonly used inert polymer, can act as an efficient triboelectric catalyst for H2O2generation. For example, a high H2O2production rate of 24.8 mmol gcat–1h–1at a dosage of 0.01 g/L PTFE was achieved under the condition of pure water, ambient atmosphere, and no sacrificial agents, which exceeds the performance of state-of-the-art aqueous H2O2powder catalysts. Electron spin resonance and isotope experiments provide strong evidence that water–PTFE tribocatalysis can directly oxidize water to produce H2O2under both anaerobic and aerobic conditions, albeit with different synthetic pathways. This study demonstrates a potential strategy for green and effective tribocatalytic H2O2production that may be particularly useful toward environmental applications.

Published
2024
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33. Synthesis and Physicochemical Transformations of Size‐Sorted Graphene Oxide during Simulated Digestion and Its Toxicological Assessment against an In Vitro Model of the Human Intestinal Epithelium

Author

Massachusetts Institute of Technology. Department of Chemical Engineering, Bitounis, Dimitrios, Parviz, Dorsa, Cao, Xiaoqiong, Amadei, Carlo A, Vecitis, Chad D, Sunderland, Elsie M, Thrall, Brian D, Fang, Mingliang, Strano, Michael S, Demokritou, Philip, Massachusetts Institute of Technology. Department of Chemical Engineering, Bitounis, Dimitrios, Parviz, Dorsa, Cao, Xiaoqiong, Amadei, Carlo A, Vecitis, Chad D, Sunderland, Elsie M, Thrall, Brian D, Fang, Mingliang, Strano, Michael S, and Demokritou, Philip

Abstract

© 2020 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim In the last decade, along with the increasing use of graphene oxide (GO) in various applications, there is also considerable interest in understanding its effects on human health. Only a few experimental approaches can simulate common routes of exposure, such as ingestion, due to the inherent complexity of the digestive tract. This study presents the synthesis of size-sorted GO of sub-micrometer- or micrometer-sized lateral dimensions, its physicochemical transformations across mouth, gastric, and small intestinal simulated digestions, and its toxicological assessment against a physiologically relevant, in vitro cellular model of the human intestinal epithelium. Results from real-time characterization of the simulated digestas of the gastrointestinal tract using multi-angle laser diffraction and field-emission scanning electron microscopy show that GO agglomerates in the gastric and small intestinal phase. Extensive morphological changes, such as folding, are also observed on GO following simulated digestion. Furthermore, X-ray photoelectron spectroscopy reveals that GO presents covalently bound N-containing groups on its surface. It is shown that the GO employed in this study undergoes reduction. Toxicological assessment of the GO small intestinal digesta over 24 h does not point to acute cytotoxicity, and examination of the intestinal epithelium under electron microscopy does not reveal histological alterations. Both sub-micrometer- and micrometer-sized GO variants elicit a 20% statistically significant increase in reactive oxygen species generation compared to the untreated control after a 6 h exposure.

Published
2021

40. Synthesis and Physicochemical Transformations of Size‐Sorted Graphene Oxide during Simulated Digestion and Its Toxicological Assessment against an In Vitro Model of the Human Intestinal Epithelium

Author

Bitounis, Dimitrios, primary, Parviz, Dorsa, additional, Cao, Xiaoqiong, additional, Amadei, Carlo A., additional, Vecitis, Chad D., additional, Sunderland, Elsie M., additional, Thrall, Brian D., additional, Fang, Mingliang, additional, Strano, Michael S., additional, and Demokritou, Philip, additional

Published
2020
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46. A review of polymeric membranes and processes for potable water reuse

Author

Massachusetts Institute of Technology. Department of Mechanical Engineering, Rohsenow Kendall Heat Transfer Laboratory (Massachusetts Institute of Technology), Warsinger, David Elan Martin, Lienhard, John H., Chakraborty, Sudip, Tow, Emily W., Plumlee, Megan H., Bellona, Christopher, Loutatidou, Savvina, Karimi, Leila, Mikelonis, Anne M., Achilli, Andrea, Ghassemi, Abbas, Padhye, Lokesh P., Snyder, Shane A., Curcio, Stefano, Vecitis, Chad D., Arafat, Hassan A., Lienhard, John H, Massachusetts Institute of Technology. Department of Mechanical Engineering, Rohsenow Kendall Heat Transfer Laboratory (Massachusetts Institute of Technology), Warsinger, David Elan Martin, Lienhard, John H., Chakraborty, Sudip, Tow, Emily W., Plumlee, Megan H., Bellona, Christopher, Loutatidou, Savvina, Karimi, Leila, Mikelonis, Anne M., Achilli, Andrea, Ghassemi, Abbas, Padhye, Lokesh P., Snyder, Shane A., Curcio, Stefano, Vecitis, Chad D., Arafat, Hassan A., and Lienhard, John H

Abstract

Conventional water resources in many regions are insufficient to meet the water needs of growing populations, thus reuse is gaining acceptance as a method of water supply augmentation. Recent advancements in membrane technology have allowed for the reclamation of municipal wastewater for the production of drinking water, i.e., potable reuse. Although public perception can be a challenge, potable reuse is often the least energy-intensive method of providing additional drinking water to water stressed regions. A variety of membranes have been developed that can remove water contaminants ranging from particles and pathogens to dissolved organic compounds and salts. Typically, potable reuse treatment plants use polymeric membranes for microfiltration or ultrafiltration in conjunction with reverse osmosis and, in some cases, nanofiltration. Membrane properties, including pore size, wettability, surface charge, roughness, thermal resistance, chemical stability, permeability, thickness and mechanical strength, vary between membranes and applications. Advancements in membrane technology including new membrane materials, coatings, and manufacturing methods, as well as emerging membrane processes such as membrane bioreactors, electrodialysis, and forward osmosis have been developed to improve selectivity, energy consumption, fouling resistance, and/or capital cost. The purpose of this review is to provide a comprehensive summary of the role of polymeric membranes and process components in the treatment of wastewater to potable water quality and to highlight recent advancements and needs in separation processes. Beyond membranes themselves, this review covers the background and history of potable reuse, and commonly used potable reuse process chains, pretreatment steps, and advanced oxidation processes. Key trends in membrane technology include novel configurations, materials, and fouling prevention techniques. Challenges still facing membrane-based potable reuse applications

Published
2018

49. A review of polymeric membranes and processes for potable water reuse

Author

Warsinger, David M., primary, Chakraborty, Sudip, additional, Tow, Emily W., additional, Plumlee, Megan H., additional, Bellona, Christopher, additional, Loutatidou, Savvina, additional, Karimi, Leila, additional, Mikelonis, Anne M., additional, Achilli, Andrea, additional, Ghassemi, Abbas, additional, Padhye, Lokesh P., additional, Snyder, Shane A., additional, Curcio, Stefano, additional, Vecitis, Chad D., additional, Arafat, Hassan A., additional, and Lienhard, John H., additional

Published
2018
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