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Impacts of Invasive Plants on Sandhill Crane (Grus canadensis) Roosting Habitat

Published online by Cambridge University Press:  20 January 2017

Andrew C. Kessler*
Affiliation:
Center for Advanced Land Management Information Technologies, University of Nebraska–Lincoln, 3310 Holdrege Street, Lincoln, NE 68583
James W. Merchant
Affiliation:
Center for Advanced Land Management Information Technologies, University of Nebraska–Lincoln, 3310 Holdrege Street, Lincoln, NE 68583
Craig R. Allen
Affiliation:
U.S. Geological Survey Nebraska Cooperative Fish and Wildlife Research Unit, University of Nebraska–Lincoln, 3310 Holdrege Street, Lincoln, NE 68583
Steven D. Shultz
Affiliation:
College of Business Administration, University of Nebraska–Omaha, Mammel Hall 332Z, 6708 Pine Street, Omaha, NE 68182
*
Corresponding author's E-mail: [email protected]

Abstract

Invasive plants continue to spread in riparian ecosystems, causing both ecological and economic damage. This research investigated the impacts of common reed, purple loosestrife, riparian shrubland, and riparian woodlands on the quality and quantity of sandhill crane roosting habitat in the central Platte River, Nebraska, using a discrete choice model. A more detailed investigation of the impacts of common reed on sandhill crane roosting habitat was performed by forecasting a spread or contraction of this invasive plant. The discrete choice model indicates that riparian woodlands had the largest negative impact on sandhill crane roosting habitat. The forecasting results predict that a contraction of common reed could increase sandhill crane habitat availability by 50%, whereas an expansion could reduce the availability by as much as 250%. This suggests that if the distribution of common reed continues to expand in the central Platte River the availability of sandhill crane roosting habitat would likely be greatly reduced.

Type
Research Article
Copyright
Copyright © Weed Science Society of America 

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References

Literature Cited

Ben-Akiva, M. and Lerman, S. R. 1985. Discrete Choice Analysis: Theory and Application to Travel Demand. Cambridge, MA MIT Press. 390 p.Google Scholar
Benning, D. S. and Johnson, D. H. 1987. Recent improvements to sandhill crane surveys in Nebraska's Central Platte Valley. Pages 1016 in Lewis, J. C., ed. Proceedings of 1985 International Crane Workshop. Grand Island, NE U.S. Fish and Wildlife Service.Google Scholar
Benoit, L. K. and Askins, R. A. 1999. Impact of the spread of common reed on the distribution of birds in Connecticut tidal marshes. Wetlands 19:194208.Google Scholar
Chambers, R. M., Meyerson, L. A., and Saltonstall, K. 1999. Expansion of Phragmites australis into tidal wetlands of North America. Aquat. Bot. 64:261273.Google Scholar
Cooper, A. B. and Millspaugh, J. J. 1999. The application of discrete choice models to wildlife resource selection studies. Ecology 80:566575.Google Scholar
Currier, P. J. and Davis, C. A. 2000. The Platte as a prairie river: a response to Johnson and Boettcher. Great Plains Res. 10:6984.Google Scholar
Davis, C. A. 2003. Habitat use and migration patterns of sandhill cranes along the Platte River, 1998–2001. Great Plains Res. 12:199216.Google Scholar
Dodds, W. K., Gido, K., Whiles, M. R., Fritz, K. M., and Matthews, W. J. 2004. Life on the edge: the ecology of Great Plains prairie streams. BioScience 54:205216.Google Scholar
Fell, P. E., Weissbach, S. P., Jones, D. A., Fallon, M. A., Zepieri, J. A., Faison, E. K., Lennon, K. A., Newberry, K. J., and Reddington, L. K. 1998. Does invasion of oligohaline tidal marshes by reed grass, Phragmites australis (Cav.) Trin. ex Steud., affect the availability of prey resources for the mummichog, Fundulus heteroclitus L.? J. Exp. Marine Biol. Ecol. 222:5077.Google Scholar
Folk, M. J. and Tacha, T. C. 1990. Sandhill crane roost site characteristics in the North Platte River Valley. J. Wildl. Manag. 54:480486.Google Scholar
Frith, C. R. 1974. The ecology of the Platte River as related to sandhill cranes and other waterfowl in south central Nebraska. M.S. thesis. Lincoln, NE University of Nebraska–Lincoln.Google Scholar
Hoffman, J. D., Narumalani, S., Mishra, D. R., Merani, P., and Wilson, R. G. 2008. Predicting potential occurrence and spread of invasive plant species along the North Platte River, Nebraska. Invasive Plant Sci. Manag. 1:359367.Google Scholar
Hudon, C., Gagnon, P., and Jean, M. 2005. Hydrological factors controlling the spread of common reed (Phragmites australis) in the St. Lawrence River (Quebec, Canada). Ecoscience 12:347357.Google Scholar
Johnson, J. B. and Omland, K. S. 2004. Model selection in ecology and evolution. Trends Ecol. Evol. 19:101108.Google Scholar
Johnson, W. C. 1994. Woodland expansion in the Platte River, Nebraska: patterns and causes. Ecol. Monogr. 64:4584.Google Scholar
Kinzel, P. J., Parker, R. S., Nelson, J. M., Starbuck, M., and Davis, L. 2001. Mapping sandhill crane roost sites along the central Platte River using aerial infrared videography. Pages 8 in Proceedings of the 11th Platte River Basin Ecosystem Symposium, February 27, 2001. Kearney, NE University of Nebraska Extension Platte Watershed Program.Google Scholar
Krapu, G. L., Iverson, G. C., Reinecke, K. J., and Boise, C. M. 1985. Fat deposition and usage by arctic-nesting sandhill cranes during spring. Auk 102:362368.Google Scholar
Marks, M., Lapin, B., and Randall, J. 1994. Phragmites australis: threats, management, and monitoring. Nat. Area. J. 14:285294.Google Scholar
McCracken, M. L., Manly, B. F. J., and Vander Heyden, M. 1998. The use of discrete-choice models for evaluating resource selection. J. Agr. Biol. Envir. St. 3:268279.Google Scholar
McDonald, T. L., Manly, F. J., Nielson, R. M., and Diller, L. V. 2006. Discrete-choice modeling in wildlife studies exemplified by northern spotted owl nighttime habitat selection. J. Wildl. Manag. 70:375383.Google Scholar
Meyer, S. W., Badzinski, S. S., Petrie, S. A., and Ankney, C. D. 2010. Seasonal abundance and species richness of birds in common reed habitats in Lake Erie. J. Wildl. Manag. 74:15591567.Google Scholar
National Research Council. 2004. Endangered and Threatened Species of the Platte River. Washington, DC National Academies. 336 p.Google Scholar
Norling, B. S., Anderson, S. H., and Hubert, W. A. 1992. Roost sites used by sandhill crane staging along the Platte River, Nebraska. Great Basin Nat. 52:253361.Google Scholar
Randall, J. M., Morse, L. E., Benton, N., Hiebert, R., Lue, S., and Killeffer, T. 2008. The invasive species assessment protocol: a tool for creating regional and national lists of invasive nonnative plants that negatively impact biodiversity. Invasive Plant Sci. Manag. 1:3649.Google Scholar
Stanley, K. E., Murphy, P. G., Prince, H. H., and Burton, T. M. 2005. Long-term ecological consequences of anthropogenic disturbance on Saginaw Bay coastal wet meadow vegetation. J. Great Lakes Res. 31:147159.Google Scholar
Wilcox, K. L., Petrie, S. A., Maynard, L. A., and Meyer, S. W. 2003. Historical distribution and abundance of Phragmites australis at Long Point, Lake Erie, ON. J. Great Lakes Res. 29:664680.Google Scholar
Williams, G. P. 1978. The case of the shrinking channels—the North Platte and Platte rivers in Nebraska. U.S. Geol. Surv. 781:48.Google Scholar