Environmental sources and treatment strategies of organic micropollutants

Abstract

Organic micropollutants (OMPs) in climate change affected natural environment such as wetlands, and engineered systems have brought serious concerns for water security and public health. These issues have increased the demand for better managing water resources and developing effective technologies for aqueous micropollutants removal. This thesis investigated these subjects through the following five sub-research projects. First, boreal peatland was used as a case study for understanding how peatland fires and droughts impacts peatland resilience. Laboratory results suggested that heating and moisture condition, coupled with peat organic hydrophobic transformations, influence peat soil hydrophobicity and the resultant water-extractable pollutant leaching, which potentially threatens peatland downstream receiving waters such as potable waters by high organic loads. Further, post-fire peat chemistry and their mechanistic relationships to leached pollutants (total organic carbon (TOC), nutrients and phenols) were elucidated through a laboratory leaching study. Increased contaminant loading was observed in post-heated peat leachates, suggesting negative effects to water treatment efficiency and an increase of treatment costs to surface waters as potable water source. Next, peat soils damaged from extreme fires and droughts were upcycled for producing high surface area, value-added porous carbons based on a rapid, facile chemical activation approach. This application had the simultaneous benefit of peatland ecological restoration, protecting downstream communities from heavy run-off, and using the sustainable damaged peats for effective environmental remediation though adsorption. Moreover, a critical review of nano-enabled composite membranes for OMP removal (size-exclusion, adsorption, charge interaction, and photo- and electro-catalysis) and their respective benefits and limitations were discussed. This work brought new perspectives for next-generation nanocomposite membranes for OMP removal. Finally, a novel, hyperbranched polyethylenimine (HPEI) crosslinked iron doped reduced graphene oxide (rGO) nanocomposite membrane was synthesized for process-intensified flow-through separation of phenolic micropollutants. Mechanisms and separation performance to phenolic micropollutant and azo dyes were investigated.