• Sustainable aquaculture​;
• Plastic and microplastic debris;
• Nutrient runoff and coastal ocean acidification; and 
• Pesticide use and water quality impacts. 

What you’ll get as a Fellow (Benefits)

Microplastics and microfibers (MP/MFs, generally defined as materials <5mm in length and including nanomaterials <1 micron) are found ubiquitously througho​​ut ocean and coastal waters globally, and they are increasingly being studied for their impacts on the environment and wildlife and human health. MP/MFs affect organisms through ingestion and inhalation and subsequent exposure to chemicals inherent to the plastic itself as well as chemicals adsorbed onto the plastic’s surface from the surrounding environment. Studies have shown that microplastics are able to translocate from an organism’s digestive tract into its body, including muscle, reproductive and brain tissue. The ultimate effects of this exposure are unknown as of yet. 

Once in the environment MP/MFs are nearly impossible to remove. Experts agree that reducing the source of the MP/MF is the most effective way of reducing this contaminant in the environment. One area warranting more investigation is the contribution of plastics from agricultural lands. Plastic ​​mulch and drip tape fragments can enter estuarine and marine environments where they break down into MP/MFs. Additionally, sludge from wastewater treatment facilities added to agricultural fields as fertilizer may be a significant source of MP/MFs, which are prevalent in household effluent. Quantification of MP/MF loads from different types of agricultural practices can help determine where efforts to mitigate plastic pollution can be most effective. 

Potential projects: Quantification of MP/MF loads from different types of agricultural practices; quantification and characterization of MP/MFs in wastewate​r sludge; impacts of MP/MF exposure on marine and aquatic life; development of bio-based materials to replace synthetics. 

Pesticides are used in agriculture to control weeds, insect populations and invasive species and play a critical role in increasing crop yields. However, pesticides can negatively impact surrounding surface waters, groundwater, and soils through runoff, infiltration, and atmospheric depositio​​n. Once in waterways, pesticides pose a threat to aquatic life as well as humans. For species such as fish and aquatic invertebrates, mechani​sms include toxicity, bioaccumulation, changes to behavior and reproduction, and changes to ecosystem balance. Human exposure to pesticide pollution occurs primarily through contamination of drinking water supplies, consumption of contaminated organisms, or contact with surface waters. 

The impact of pesticides on water quality and ecosystems is a result of environmental conditions (e.g., precipitation, soil characteristics), hydrology, pesti​​cide chemistry (e.g., solubility, mobility), and management and may be highly site-specific. Better understanding of dynamics at individual sites could allow for tailored, site-specific management practices that increase efficiency and effectiveness. 

Potential projec​​ts: Site-specific studies to understand local dynamics and develop tailor-made strategies to reduce contamination of the surrounding environment; development of more universal best management practices to reduce contamination; development of more environmentally-friendly products and nature-based solutions to pest management.