Phosphate Elimination and Recovery Lightweight (PEARL) membrane: A sustainable environmental remediation approach

Abstract: Aqueous phosphate pollution can dramatically impact ecosystems, introducing a variety of environmental, economic, and public health problems. While novel remediation tactics based on nanoparticle binding have shown considerable promise in nutrient recovery from water, they are challenging to deploy at scale. To bridge the gap between the laboratory-scale nature of these nanostructure solutions and the practical benchmarks for deploying an environmental remediation tool, we have developed a nanocomposite materi… Show more

“…The reduction of dissolved O 2 impacts the survival of fish and other aquatic animals. 3 Hence, a polymer with inherent biocide activity would provide an extra benefit over other such materials. The presence of guanidinium moieties also inspired us to investigate the antibacterial activities of the gCONs.…”

“…In addition, the increased methane gas emission due to eutrophication is comparable to 18–33% of the yearly CO 2 released from burning fossil fuels. 2,3…”

Antimicrobial two-dimensional covalent organic nanosheets (2D-CONs) for the fast and highly efficient capture and recovery of phosphate ions from water

“…The reduction of dissolved O 2 impacts the survival of fish and other aquatic animals. 3 Hence, a polymer with inherent biocide activity would provide an extra benefit over other such materials. The presence of guanidinium moieties also inspired us to investigate the antibacterial activities of the gCONs.…”

“…In addition, the increased methane gas emission due to eutrophication is comparable to 18–33% of the yearly CO 2 released from burning fossil fuels. 2,3…”

Antimicrobial two-dimensional covalent organic nanosheets (2D-CONs) for the fast and highly efficient capture and recovery of phosphate ions from water

“…Brockgreitens et al developed a “Crescoating” approach, by which iron nanoparticles have been directly grown on polyurethane sponges that displays a remarkably enhanced adsorption affinity and much more rapid adsorption kinetic for capturing P compared to commercial alternatives. Using a dip-coating method, Ribet and colleagues synthesized a Fe 3 O 4 -laden Cellulose sponge (referred to as “PEARL”), which can selectively capture up to 99% of P from wastewater at environmentally relevant concentrations. A recent study shows that the melamine sponge (MS) composite anchored with ZIF-8 exhibited excellent oil/water separation performance due to the synergistic effect from the advantages of both ZIF-8 and MS scaffolds .…”

Anchoring NH₂-MIL-101(Fe/Ce) within Melamine Sponge Boosts Rapid Adsorption and Recovery of Phosphate from Water

“…This composite material leverages the hierarchical porosity, robustness, and deployability advantages of cellulose membranes with the large surface area and high selectivity of metal oxide nanoparticles. These nanoparticles (magnetite, manganese-doped goethite, alumina, and zinc oxide) were selected due to high level of academic interest in their use for water remediation and for their low cost and green synthesis routes. − The resulting sponge nanocomposites have been found to be effective materials for attacking contemporary environmental problems such as oil spill remediation and nutrient recovery . After our previous success with respect to these problems, we looked at the adsorption and recovery of heavy metals in water as a logical next step.…”

Nano-SCHeMe: Nanomaterial Sponge Coatings for Heavy Metals, an Environmental Remediation Platform