How and why do species assemble in space and time? These questions are foundational to community ecology and provide the overarching framework for my research program. I use rigorous observational and experimental field studies, complemented by targeted laboratory and greenhouse experiments, to answer fundamental questions about the ways that human-mediated environmental change (e.g., invasive species, land use changes, urbanization, climate change, etc.) and natural environmental gradients (e.g., nutrient subsidies, disturbances, latitude, etc.) affect the composition and structure of communities and the ecological functions they perform.
I am currently a Hakai Institute Coastal Initiatives postdoctoral scholar in the Tseng Lab at the University of British Columbia, and am also a member of the Reynolds Lab at Simon Fraser University, where I held a Hakai postdoctoral fellowship for three years prior. Since 2015 I’ve been the lead investigator of the terrestrial invertebrate component of the 100 Islands Project: a multidisciplinary subsidized island biogeography study taking place on British Columbia’s beautiful central coast. Invertebrates – insects, spiders, snails, slugs, and other creepy-crawlies – perform critical functions in all terrestrial ecosystems. On the 1600+ islands along BC’s central coast, invertebrates decompose seaweed wrack, pollinate endemic plants, and provide important food sources for breeding birds and small mammals. Understanding why some invertebrates exist on certain islands and others don’t can provide important insights into island food webs, and this information can be used to inform decisions about biodiversity conservation and monitoring.
In addition to performing invertebrate biodiversity surveys on roughly 100 islands, I’m testing predictions about the relationships between invertebrate diversity and: a) spatial and physical characteristics of islands, like area and distance from the mainland; b) the input of marine-derived nutrient subsidies on islands by passive (ocean waves/wind) and active (ocean-going mammals) means, and; c) interactions between invertebrates and other organisms.
My earlier work in the Arctic seeded in me a passion for studying diversity in rugged, remote landscapes, so I am excited to work in this challenging and beautiful coastal system.
My doctoral studies at McGill University took me to Arctic Canada, a region of tremendous social and ecological significance facing serious environmental threats. Despite the fact that arthropods are critical components of northern ecosystems and perform many important ecological functions, they are poorly understood.
I used arthropod communities from Arctic Canada to study large-scale patterns of species distribution, diversity and community structure. Beetles were the principal model taxon in my research.
To determine the underlying mechanisms responsible for temporal patterns of biodiversity, as well as patterns on a large spatial scale, I tested whether spatial, biotic or climatic variables explained latitudinal gradients of species diversity, taxonomic assemblage structure, and trait-based functional diversity. Climate, especially temperature, appears to be the most significant driver at this cross-continental spatial extent.
What are some of the highlights of this work?
1. It’s one of the largest standardized, field-based studies of terrestrial biodiversity patterns and processes, and one of few that has tested relationships between species diversity, ecological functions, and mechanistic processes at this scale.
2. Over 11,000 beetle specimens – including uncommon, rare, or new species – are now deposited in three internationally significant entomological research collections, and 9000 of these records are open-access (check them out here!)
3. I found all kinds of evidence that temperature is one of the most important factors influencing patterns of terrestrial arthropod biodiversity, both over time and over very large geographic areas
4. I provided evidence that niche complementarity plays an important role in shaping arthropod community structure at a large spatial scale, but it’s essentially overridden by environmental constraints (it’s super-cold!) in the high arctic
5. I show that northern arthropod communities may conform to an uncommon trophic structure known as an inverted pyramid; they’re weird and unique!
6. In a really fun, and totally unexpected side project, I did a natural history study of arctic host-parasite relationships between ground beetles and new species of horsehair worm. It’s the first of it’s kind in the world, and highlights new host associations and a new parasite species! It also tells us more about the prey and diets of northern ground beetles, and shows that aquatic habitats probably act as important sources of food for terrestrial predators.
7. All in all, the study highlights that fact that northern terrestrial diversity is dominated by a rich and unique arthropod fauna that reflects environmental (particularly climate) changes in their diversity, distribution, and assemblage structure, making them ideal animals for targeted long-term diversity monitoring in the arctic.
My work represented a component of the Northern Biodiversity Program.
Ph.D., Entomology, McGill University (Ste-Anne-de-Bellevue, QC) 2015
Thesis: “Patterns and drivers of terrestrial arthropod biodiversity in northern Canada”)”
Advisor: Dr. Christopher Buddle
M.Sc., Biology, Carleton University (Ottawa, ON) 2005
Thesis: “Host plants, biology and chemical ecology of the introduced lily leaf beetle, Lilioceris lilii Scopoli (Coleoptera: Chrysomelidae)”
Advisor: Dr. Naomi Cappuccino
B.Sc. Hons., Biology, Carleton University (Ottawa,ON) 2003
Thesis: “The effects of an invasive alien vine, Vincetoxicum rossicum (Asclepiadaceae) on arthropod populations in old fields”
Advisor: Dr. Naomi Cappuccino