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Description: <div>Anderson AM, Duijns S, Smith PA, Friis C, Nol E. 2019. Migration Distance and Body Condition Influence Shorebird Migration Strategies and Stopover Decisions During Southbound Migration. Frontiers in Ecology and Evolution 7. Available from <a href="https://www.frontiersin.org/journals/ecology-and-evolution/articles/10.3389/fevo.2019.00251/full" target="_blank">https://www.frontiersin.org/journals/ecology-and-evolution/articles/10.3389/fevo.2019.00251/full</a> (accessed July 9, 2019).</div><div><br /></div><div>Anderson AM, Friis C, Gratto-Trevor CL, Harris CM, Love OP, Morrison RIG, Prosser SWJ, Nol E, Smith PA. 2021. Drought at a coastal wetland affects refuelling and migration strategies of shorebirds. OecologiaDOI: 10.1007/s00442-021-05047-x. Available from <a href="https://doi.org/10.1007/s00442-021-05047-x" target="_blank">https://doi.org/10.1007/s00442-021-05047-x</a> (accessed October 27, 2021).</div><div><br /></div><div>Aubry Y, Desrochers A, MacDonald A, Tremblay J EC-Quebec-St. 2014–2019. EC-Quebec-St Laurent (Project 3). Data accessed from Motus Wildlife Tracking System, Birds Canada. Available from <a href="https://motus.org" target="_blank">https://motus.org</a> (accessed February 7, 2025).</div><div><br /></div><div>Bianchini K, Morrissey CA. 2018. Assessment of Shorebird Migratory Fueling Physiology and Departure Timing in Relation to Polycyclic Aromatic Hydrocarbon Contamination in the Gulf of Mexico. Environmental Science &amp; TechnologyDOI: 10.1021/acs.est.8b04571. Available from <a href="https://doi.org/10.1021/acs.est.8b04571" target="_blank">https://doi.org/10.1021/acs.est.8b04571</a> (accessed November 9, 2018).</div><div><br /></div><div>Bianchini K, Newstead DJ, Morrissey CA. 2020. Differences in Migration Timing along the Midcontinental Flyway in Sanderling (Calidris alba) from Three Gulf of Mexico Staging Areas. Waterbirds 43:225–356. Available from <a href="https://bioone.org/journals/waterbirds/volume-43/issue-3-4/063.043.0301/Differences-in-Migration-Timing-along-the-Midcontinental-Flyway-in-Sanderling/10.1675/063.043.0301.full" target="_blank">https://bioone.org/journals/waterbirds/volume-43/issue-3-4/063.043.0301/Differences-in-Migration-Timing-along-the-Midcontinental-Flyway-in-Sanderling/10.1675/063.043.0301.full</a> (accessed September 21, 2021).</div><div><br /></div><div>Bianchini K. 2018, December. Investigating the effects of polycyclic aromatic hydrocarbon exposure on avian pre-migratory fuelling and migration. PhD Thesis. University of Saskatchewan.</div><div><br /></div><div>Desrochers A, Tremblay JA, Aubry Y, Chabot D, Pace P, Bird DM. 2018. Estimating Wildlife Tag Location Errors from a VHF Receiver Mounted on a Drone. Drones 2:44. Available from <a href="https://www.mdpi.com/2504-446X/2/4/44" target="_blank">https://www.mdpi.com/2504-446X/2/4/44</a> (accessed December 16, 2018).</div><div><br /></div><div>Duijns S et al. 2019. Long-distance migratory shorebirds travel faster towards their breeding grounds, but fly faster post-breeding. Scientific Reports 9:9420. Available from <a href="https://www.nature.com/articles/s41598-019-45862-0" target="_blank">https://www.nature.com/articles/s41598-019-45862-0</a> (accessed July 6, 2019).</div><div><br /></div><div>Duijns S, Niles LJ, Dey A, Aubry Y, Friis C, Koch S, Anderson AM, Smith PA. 2017. Body condition explains migratory performance of a long-distance migrant. Proceedings of the Royal Society B: Biological Sciences 284:20171374. Available from <a href="http://rspb.royalsocietypublishing.org/lookup/doi/10.1098/rspb.2017.1374" target="_blank">http://rspb.royalsocietypublishing.org/lookup/doi/10.1098/rspb.2017.1374</a> (accessed November 2, 2017).</div><div><br /></div><div>Friis C, Anderson A, Bennett K, Loring P, MacDonald A, Smith P, Wood R. 2014–2019. James Bay Shorebirds (Project 38). Data accessed from Motus Wildlife Tracking System, Birds Canada. Available from <a href="https://motus.org" target="_blank">https://motus.org</a> (accessed February 7, 2025).</div><div><br /></div><div>Howell JE, McKellar AE, Espie RHM, Morrissey CA. 2019. Predictable shorebird departure patterns from a staging site can inform collision risks and mitigation of wind energy developments. Ibis 0. Available from <a href="https://onlinelibrary.wiley.com/doi/abs/10.1111/ibi.12771" target="_blank">https://onlinelibrary.wiley.com/doi/abs/10.1111/ibi.12771</a> (accessed August 26, 2019).</div><div><br /></div><div>Howell JE, McKellar AE, Espie RHM, Morrissey CA. 2019. Spring Shorebird Migration Chronology and Stopover Duration at an Important Staging Site in the North American Central Flyway. Waterbirds 42:8–21. Available from <a href="https://bioone.org/journals/Waterbirds/volume-42/issue-1/063.042.0102/Spring-Shorebird-Migration-Chronology-and-Stopover-Duration-at-an-Important/10.1675/063.042.0102.full" target="_blank">https://bioone.org/journals/Waterbirds/volume-42/issue-1/063.042.0102/Spring-Shorebird-Migration-Chronology-and-Stopover-Duration-at-an-Important/10.1675/063.042.0102.full</a> (accessed April 2, 2019).</div><div><br /></div><div>Koch S, Loring P, MacDonald A, O’Brien K, pau n, Smith P. 2014–2018. Monomoy - Steph Koch (Project 88). Data accessed from Motus Wildlife Tracking System, Birds Canada. Available from <a href="https://motus.org" target="_blank">https://motus.org</a> (accessed February 7, 2025).</div><div><br /></div><div>Lefevre K, Smith A. 2017–2019. Florida Gulf Coast University (Project 96). Data accessed from Motus Wildlife Tracking System, Birds Canada. Available from <a href="https://motus.org" target="_blank">https://motus.org</a> (accessed February 7, 2025).</div><div><br /></div><div>Lefevre KL, Forys E, DiNuovo A, Smith AD. 2023. Insights from attempts to track movement of Black Skimmer (&lt;em&gt;Rynchops niger&lt;/em&gt;) fledglings in the southern Gulf of Mexico with automated telemetry and band resighting. Journal of Caribbean Ornithology 36:107–113. Available from <a href="https://jco.birdscaribbean.org/index.php/jco/article/download/1382/1033" target="_blank">https://jco.birdscaribbean.org/index.php/jco/article/download/1382/1033</a> (accessed October 29, 2023).</div><div><br /></div><div>Loring PH, Lenske AK, McLaren JD, Aikens M, Anderson AM, Aubrey Y, Dalton E, Dey A, Friis C, Hamilton D. 2021. Tracking Movements of Migratory Shorebirds in the US Atlantic Outer Continental Shelf Region. Page 104. BOEM 2021-008, OCS Study. Sterling (VA): US Department of the Interior, Bureau of Ocean Energy Management. OCS Study BOEM. Available from <a href="https://www.boem.gov/sites/default/files/documents/renewable-energy/studies/Tracking-Migratory-Shorebirds-Atlantic-OCS.pdf" target="_blank">https://www.boem.gov/sites/default/files/documents/renewable-energy/studies/Tracking-Migratory-Shorebirds-Atlantic-OCS.pdf</a>.</div><div><br /></div><div>Mackenzie S, Smith A. 2017–2019. Bahia Lomas Shorebirds (Project 174). Data accessed from Motus Wildlife Tracking System, Birds Canada. Available from <a href="https://motus.org" target="_blank">https://motus.org</a> (accessed February 7, 2025).</div><div><br /></div><div>Marsh B. 2023. Red Knot Tracking Project, Mispillion Harbor, DE - Delaware Shorebird Project. Available from <a href="https://www.movebank.org/cms/webapp?gwt_fragment=page%3Dstudies%2Cpath%3Dstudy2783096023" target="_blank">https://www.movebank.org/cms/webapp?gwt_fragment=page%3Dstudies%2Cpath%3Dstudy2783096023</a> (accessed January 6, 2025).</div><div><br /></div><div>McKellar AE, Ross RK, Morrison RIG, Niles LJ, Porter RR, Burger J, Newstead DJ, Dey AD, Smith PA. 2015. Shorebird use of western Hudson Bay near the Nelson River during migration, with a focus on Red Knot. Wade Study 122. Available from <a href="https://www.researchgate.net/profile/R_Morrison/publication/283682304" target="_blank">https://www.researchgate.net/profile/R_Morrison/publication/283682304</a> (accessed November 3, 2015).</div><div><br /></div><div>Morrissey C, McKellar A, Smith P. 2015–2020. Saskatchewan Migratory Shorebirds (Project 63). Data accessed from Motus Wildlife Tracking System, Birds Canada. Available from <a href="https://motus.org" target="_blank">https://motus.org</a> (accessed February 7, 2025).</div><div><br /></div><div>Morrissey C, Newstead D, Heath S, McKellar A. 2016. Texas Gulf Coast Migratory Shorebirds (Project 65). Data accessed from Motus Wildlife Tracking System, Birds Canada. Available from <a href="https://motus.org" target="_blank">https://motus.org</a> (accessed February 7, 2025).</div><div><br /></div><div>Niles L, Koch S, Loring P, Smith P. 2014–2021. Red Knot Staging and Migration Ecology (Project 47). Data accessed from Motus Wildlife Tracking System, Birds Canada. Available from <a href="https://motus.org" target="_blank">https://motus.org</a> (accessed February 7, 2025).</div><div><br /></div><div>Olek V. 2021, November 15. Exploring the Strategies of First Migration in the Subarctic-Nesting Shorebird, Calidris Alpina Hudsonia. Master of Science. York University, Toronto. Available from <a href="https://yorkspace.library.yorku.ca/xmlui/handle/10315/38639" target="_blank">https://yorkspace.library.yorku.ca/xmlui/handle/10315/38639</a> (accessed November 20, 2021).</div><div><br /></div><div>Sanders F, Smith A, Thibault J, Carter D, Handmaker M, Smith F. 2023. South Atlantic Bight – a final stop for Ruddy Turnstones migrating to the Arctic. Journal of Field Ornithology 94:art5. Available from <a href="https://journal.afonet.org/vol94/iss2/art5/" target="_blank">https://journal.afonet.org/vol94/iss2/art5/</a> (accessed August 21, 2023).</div><div><br /></div><div>Sanders F, Smith A. 2017–2021. SCDNR Shorebirds (Project 140). Data accessed from Motus Wildlife Tracking System, Birds Canada. Available from <a href="https://motus.org" target="_blank">https://motus.org</a> (accessed February 7, 2025).</div><div><br /></div><div>Scarpignato A, Harrison A-L, Newstead D, Niles L, Porter R, Tillaart M, Marra PP. 2016. Field-testing a new miniaturized GPS-Argos satellite transmitter (3.5 g) on migratory shorebirds. Wader Study 123. Available from <a href="http://dx.doi.org/10.18194/ws.00046" target="_blank">http://dx.doi.org/10.18194/ws.00046</a> (accessed February 18, 2022).</div><div><br /></div><div>Smith A, Marain D. 2015–2020. Region 4 USFWS (Project 4). Data accessed from Motus Wildlife Tracking System, Birds Canada. Available from <a href="https://motus.org" target="_blank">https://motus.org</a> (accessed February 7, 2025).</div><div><br /></div><div>Smith AD, Sanders FJ, Lefevre KL, Thibault JM, Kalasz KS, Handmaker MC, Smith FM, Keyes TS. 2023. Spring migration patterns of red knots in the Southeast United States disentangled using automated telemetry. Scientific Reports 13:11138. Available from <a href="https://www.nature.com/articles/s41598-023-37517-y" target="_blank">https://www.nature.com/articles/s41598-023-37517-y</a> (accessed August 21, 2023).</div><div><br /></div><div>Tremblay JA, Desrochers A, Aubry Y, Pace P, Bird DM. 2017. A Low-Cost Technique for Radio-Tracking Wildlife Using a Small Standard Unmanned Aerial Vehicle. Journal of Unmanned Vehicle SystemsDOI: 10.1139/juvs-2016-0021. Available from <a href="http://www.nrcresearchpress.com/doi/abs/10.1139/juvs-2016-0021" target="_blank">http://www.nrcresearchpress.com/doi/abs/10.1139/juvs-2016-0021</a> (accessed April 9, 2017).</div>

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