**ABSTRACT NOT FOR CITATION WITHOUT AUTHOR PERMISSION. The title, authors, and abstract for this completion report are provided below.  For a copy of the full completion report, please contact the author via e-mail at suski@illinois.edu or via telephone at 217-244-2237. Questions? Contact the GLFC via email at frp@glfc.org or via telephone at 734-662-3209.**





Cory D. Suski1, Adam W. Wright1, and Clark E. Dennis III1,2



1University of Illinois, Department of Natural Resources and Environmental Sciences, 1102 S. Goodwin Ave, Urbana, IL 61801, USA


2Present address: University of Minnesota, Department of Fisheries, Wildlife and Conservation Biology, 135E Skok Hall, 2003 Upper Buford Circle, St. Paul, MN 55108, USA



April 2015




Invasive sea lamprey have had substantial negative ecological and economic impacts on the Great Lakes region.  Control efforts, such as lampricide application and barriers, have resulted in a reduction in numbers of sea lamprey in the Great Lakes.  Due to environmental and non-target impacts of existing control mechanisms, coupled with the fact that no non-physical barrier is completely effective at stopping fish movement, there is a critical need to develop novel control technologies to assist with the control and suppression of sea lamprey populations.  Recent work has suggested that carbon dioxide gas (CO2) applied to water will influence the movement and behavior of fishes, providing the potential for CO2 to act as a non-physical barrier that can exclude fish from a target area.  To date, the effectiveness of CO2 at influencing the movement and behavior of sea lamprey has not been explored.  The current study showed that CO2 applied to water will result in behavioral agitation for both adult and transformer sea lamprey, and will eventually result in equilibrium loss.  More importantly, both adult and transformer sea lamprey will ‘choose’ to avoid water with CO2 concentrations of 85 and 160 mg/L (respectively).  Together, results from this study suggest that CO2 applied to water has the potential to act as a non-physical barrier to deter the movement of free-swimming lamprey in the wild.  Carbon dioxide gas can be integrated with existing control technologies to act as a novel barrier technology and augment existing control strategies for sea lamprey.