Carly S
- Research Program Mentor
PhD at University of Texas Austin (UT Austin)
Expertise
coral biology, environmental changes, marine ecosystems, applications of math to ecology, how ocean dynamics affect marine life, how organisms specialize for their environments, how hybridization affects the potential of species, using models to connect to real-world systems, interactions of social factors and the environment, spatial statistics projects, symbiosis, landscape genetics, microbial interactions
Bio
I am a postdoctoral researcher at the University of North Carolina studying how diseases spread in grass ecosystems. I received my PhD in 2024 from the University of Texas, where I studied how climate change affects coral reefs. I primarily do this through ancient DNA (think Jurassic Park, but less scary!) and mathematical models of coral bleaching. Before starting my PhD work, I studied Applied Math and Biology at the University of Idaho. There, I applied my quantitative tool kit to a variety of projects, from analyzing the factors that affect water quality perception in Ecuador to modeling the interactions of bacteria and their predators to how evolution is influencing biocontrol beetles. Above all else, I am interested in how we can apply quantitative and computational techniques to real world problems - from sociology to evolution. When I'm not in the lab, you can find me rock climbing outdoors and cooking... I make a mean vegetarian Korean BBQ wrap! I try to weave my passions into my work whenever possible, whether through making tasty meals during field work or thinking about the impacts of human activities on the environments I enjoy.Project ideas
A Reef's Best Frenemies
Coral reefs are in global decline. A primary cause of this is "coral bleaching" which results in the white reefs we often see in the news. Coral bleaching is actually the breakdown in the partnership between the coral animal and tiny, symbiotic algae that live within its cells. Corals and algae have a variety of thermal tolerances which are likely decided by genetic and environmental factors. However, despite how important this relationship is, it's currently very poorly understood. This project would review existing literature on the symbiotic partner and try to identify factors that predict bleaching and thermal resilience.
The Future of Ancient DNA
Ancient DNA is growing more popular as our genetic sequencing technology becomes more advanced. Last year, the Nobel prize in physiology and medicine was given to one of the pioneers of ancient DNA! With it's increasing popularity, it's important to understand what questions ancient DNA can and should be applied to. There are many limitations with this type of data and a comprehensive review has yet to be done on best practices. This project would look at how ancient DNA research is being conducted across many species of plant and animal and summarize what the best way to do research going forward would be.