• Determine the concentrations and speciation of PFAS in important Lake Michigan sportfish
• Evaluate dietary routes for PFAS exposure from prey to predator fish using δ15N and δ13C stable isotopes along with PFAS speciation
• Assess the relationship between total fluorine and PFAS concentrations to determine the full extent of the PFAS problem
• Compare observed PFAS concentrations in fish from Illinois-Indiana waters to other areas such as inland Michigan waterways where PFAS are known to be a problem

In North America, there are two subspecies of Banded Killifish (Fundulus diaphanus): the Eastern Banded Killifish (F. d. diaphanus) and the Western Banded Killifish (F. d. menona). While Banded Killifish are considered secure across their range, some populations of Western Banded Killifish are considered Vulnerable or Threatened and populations of Eastern Banded Killifish are expanding rapidly into new regions. Subtle differences in the ecology between subspecies has been found to have strong effects on community composition and energy pathways in freshwater ecosystems. Potential ecological differences between Eastern and Western Banded Killifish are unstudied, therefore through this graduate student scholars project we seek to investigate the trophic ecology of Banded Killifish populations from Illinois and Indiana. Using stable isotope analysis, we can determine whether there is an ecological difference in trophic position and dietary niche width between the two subspecies, as well as how the invasion of the Eastern subspecies could impact the Western subspecies and freshwater communities or ecosystems more generally.

The objective of this research is to quantify differences molecular level genetic damage to bullhead catfish in the heavily contaminated Lake George reservoir versus levels of damage in bullhead catfish from the virtually uncontaminated Jasper Pulaski reservoir using the alkaline DNA unwinding method.

Aquatic invasive species pose a serious threat to aquatic ecosystems. In the Great Lakes, new fish species that are non-native to the environment have been introduced due to transoceanic activities. These species compete with native species causing a heavy toll on the environment and economy by shifting ecological balances and disrupting food chains. While many methods exist to sample fish, due to the increasing availability of underwater video, fish can now be sampled by crowd sourcing or using Image recognition techniques. These methods have highlighted the challenges associated with identifying fish based on their appearance against a cluttered background. This graduate student scholars project aims to identify and model fish behavior in underwater video using machine learning methods that are suited for classification of classification of time series data. Video data of round goby (Neogobius melanostomus) from literature will be used to test the approach. The methods proposed here will significantly increase the usability of existing datasets and enable the creation of life-like animations for use in virtual training environments. 

Quantifying the introductory impacts of an artificial reef on the nearshore community in Lake Michigan have not been made a priority in any experimental design. This project aims to mend this lack of understanding by combining biology and geology to create a new understanding of the effects of a newly constructed artificial reef (Rubble Ridges). This will be accomplished by observing the effects of sediment accumulation around a newly constructed artificial reef on benthic community diversity and growth. Sampling at the reef site will include sampling for invertebrates, encrusting organisms, and fish once a month during the sampling season. We will compare the trends from the Rubble Ridges site to the trends from the control site.

The objectives for this study are (1) to determine the difference in abundance and diversity of benthic organisms between the submerged shoreline stabilization structure site and the control site over a 2-year period, (2) to determine if the development of nearshore artificial reefs positively impact benthic communities in Southern Lake Michigan, and (3) to determine if benthic community diversity and abundance changes due to sediment accumulation and changes in sand grain size. We hypothesize that there will be an increase in abundance and diversity in benthic communities at the submerged shoreline stabilization structure site in comparison to the control site, that these artificial reefs will have a positive impact on the benthic communities in Southern Lake Michigan, and that sediment accumulation and larger sand grain size provide suitable habitat areas that will increase the diversity and abundance of the surrounding benthic community. Project managers and scientists can utilize this information in upcoming projects, whose intent is to prevent shoreline erosion, as a means to further understand this relationship.

Submerged, “reef-style” breakwaters may be a viable nature-based solution for shoreline protection and ecological enhancement. However, the lack of quantitative data on the effectiveness of such nature-based solutions limits the ability of managers to implement them within Great Lakes coastal communities.

Our goals are to use monitoring data to (a) inform habitat restoration and protection efforts around Lake Michigan and other Great Lakes, and (b) provide the much needed geomorphic and sediment-routing context to help assess the regional impacts of such structures (and their broader utility). We will accomplish these goals through the following objectives: Obj 1) Determine the effect of the two different artificial reefs on aquatic species abundance and diversity through comparisons to long-term (2016-present) ecological monitoring sites co-located with the reefs. Obj 2) Quantify bathymetric changes to the nearshore environment surrounding the reefs and topographic changes to the adjacent beach environment, evaluating post-reef morphodynamics in context of available pre-construction data (post-2018 at Site 1). Obj 3) Engage a variety of coastal stakeholder groups by way of discussion forums, workshops, fact sheets, or other meeting types. 

• Quantify contaminant levels in salmon and stream-resident fish at three sites at the southern end of Lake Michigan

Our overall goal is to provide quantitative  descriptions of species characteristics that increase the probability of successful invasion.

To evaluate the effect of culture temperature on growth, survival, and body composition of largemouth bass.