If interested in doing research at Trout Lake Field Station please contact Susan Knight, Station Interim Associate Director or call 715-356-9494
There are many research projects at Trout Lake Station. Below are links to several of our long term projects.
North Temperate Lakes Long-Term Ecological Research
Microbial Observatory – McMahon Lab, Univ of WI-Madison
Global Lake Ecological Observatory Network (GLEON)
USGS Water Energy Biogeochemical Budget
Along with the long term projects we have undergrads, grad students, post doc and visiting faculty conducting research at the station. These include but are not limited to:
Dr. Noah Lottig:I am an Assistant Scientist and Site Manager with the North Temperate Lakes Long Term Ecological Research Program. My primary research interests focus around ecosystem ecology and landscape limnology. I am particularly interested in understanding the long-term dynamics of aquatic ecosystems as well as the role aquatic ecosystems play in the regional and global carbon cycle.
Dr. Tom Rooney: My research group and I are testing protocols garlic mustard eradication. We are performing a population census, collecting demographic data, and implementing control procedures. Now in its 7th year, we have seen the garlic mustard population decline by over 80%.
Dr. Carl Watras, WDNR research scientist, Limnological investigations of northern lakes and wetlands, with an emphasis on atmospheric contaminants (mercury and acid rain), water budgets and carbon cycling. Biogeochemical studies of acid rain and mercury began at the Trout Lake Station (TLS) in the early 1980’s, focusing initially on a whole lake experiment in Little Rock Lake, a small (0.2 km2) precipitation-dominated, seepage lake situated in an undisturbed watershed about 5 km from TLS. The whole lake experiment evolved into a synoptic study of relationships between lake acidification and mercury bioaccumulation after it was observed that concentrations of highly toxic methylmercury (meHg) increased in water, phytoplankton, zooplankton, and fish during experimental acidification – and then returned to background levels during recovery.The synoptic studies have shown further that water level fluctuations and organic carbon export from wetlands also play a role in lake acidification and mercury contamination.These observations prompted intensive studies of wetland hydrodynamics using wireless sensor networks to track fluctuations in water levels and the flow of critical solutes over time scales ranging from hours to years (www.wetlands.gleon.org). They also prompted investigations that revealed a climatically-driven, near-decadal oscillation that has dominated the regional water cycle for most of the last century (www.news.wisc.edu/22467).
Alex Linz: Although you can’t see them, microbes are crucial members of freshwater ecosystems. Microbes are responsible for decomposition, recycling of nutrients, and harvesting nutrients from the atmosphere. They are a major food source for larger organisms, and changes in the microbial community can impact the entire lake. At the Microbial Observatory, we collect and analyze microbial samples from the same lakes over many years – we’ve been doing this for over a decade! Our goal is to understand how microbial communities change over long time scales, what drives that change, and how that affects the larger ecosystem. mcmahonlab.wisc.edu
Pete Guiden: Our work seeks to understand the response of small mammal activity to changes in winter climate. Small mammals consume many ecologically and commercially valuable tree species, and may have underappreciated effects in the winter. However, winters are warming and snowfall is decreasing, which could change the effect of small mammals on tree seed survival. To test this idea, we remove snow from small areas within forests and monitor seed survival and small mammal activity. We hope this work improves management of Wisconsin’s ecologically and economically important tree species by identifying conditions that minimize seed consumption by small mammals.
Dom Ciruzzi: As drought variability is expected to increase across the globe thus varying timing and quantity of water available for forests, it is critical to evaluate ecosystem attributes that reduce drought impacts. Through this research, we plan to evaluate groundwater use by trees as an ecosystem attribute that buffers against the potential adverse impacts of changing drought regimes on temperate forests. We are developing innovative tools to detect drought responses (e.g. water stress) of trees and how these responses may be mediated by shallow groundwater through fieldwork and numerical modeling designed to capture below- and above-ground ecohydrologic processes. website: www.domciruzzi.com
K. Martin Perales:Fish communities in northern lakes of Wisconsin are changing; cool-water species are declining as warm-water species are expanding. Understanding the drivers and consequences of these fish community changes are of primary interest to agency and University of Wisconsin aquatic ecologists. Our research will focus on characterizing the abundance/distribution of several fish species and their prey resources throughout the seasons.
Holly Embke: Walleye, a culturally, economically, and ecologically important sportfish in much of North America, has experienced declines in recent years. The cause of these declines is not understood, but is likely due to a combination of factors, such as temperature changes, harvest, and species interactions. As part of a multi-year project to understand the mechanisms underlying how Walleye are affected by other fishes, we will be conducting an experiment on McDermott Lake. We will remove as many bass and sunfish from this lake as possible to determine if there is an interaction between these fishes and walleye.
Chris Sullivan: Reproductive success of Walleyes has declined in many northern Wisconsin lakes, which is a concern for the Wisconsin DNR that manages these fisheries. Evidence suggests that populations of Largemouth Bass and other Centrarchid species have expanded and some biologists have hypothesized that these other fish are affecting Walleye reproductive success. We will conduct an experiment to determine whether this might be the case, by removing Centrarchid fish species such as Bass and Bluegills from a lake to determine if Walleye reproductive success (i.e., number of age-0 fish collected in fall) improves following the removal.
Steve Tyndel: The purpose of this study is to examine the role of social information in habitat selection in Golden-winged (GWWA) and Blue-winged Warblers (BWWA). Our objectives are to determine if conspecific social information can be used to induce settlement in both GWWA and BWWA across their range, how each species responds to heterospecific cues (how BWWA respond to GWWA calls and vice versa) and whether responses differ in allopatric and sympatric populations. Study sites include an allopatric area of GWWA (Vilas County, WI), an allopatric population of BWWA (Vermillion County, Illinois), and a sympatric population of both species (Monroe County, WI).
Paul Schramm: I will be sampling lakes using the FLAMe (flame.wisc.edu) sensor platform to build a model linking surface water chemistry to light attenuation across a gradient of lakes.
Eric Larson: We are investigating relationships between invasive crayfish behavior and diet on gradients of potential intraspecific competition, from lakes with relatively few crayfish to hyper-abundant populations. We are curious if intraspecific competition gives rise to greater individual specialization of both laboratory behaviors and field diets, as inferred by stable isotopes.
Mike Spears: Our research question is whether quantification of environmental DNA can be used to estimate walleye populations (abundance or biomass) in northern Wisconsin lakes. We are comparing our ability to quantify walleye DNA filtered and extracted from lake water to the DNR’s estimates of walleye populations from their mark-recapture netting and electrofishing.