Journal of Wildlife Management

Spatially explicit estimates of elk population demographics in North Carolina, USA

Jessica L. Braunstein ¹

Joseph D Clark ²

Ben C Augustine ³

Caleb R Hickman ⁴

Justin McVey ⁵

Joseph Yarkovich ⁶

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School of Natural Resources University of Tennessee 112 Plant Biotech, 2505 EJ Chapman Drive Knoxville 37996 TN USA

U.S. Geological Survey, Northern Rocky Mountain Science Center 112 Plant Biotech, 2505 EJ Chapman Drive, University of Tennessee Knoxville 37996 TN USA

U.S. Geological Survey, Northern Rocky Mountain Science Center 2327 University Way Suite 2 Bozeman 59715 MT USA

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Eastern Band of Cherokee Indians, Fisheries and Wildlife Management P.O. Box 1747 Cherokee 28719 NC USA

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North Carolina Wildlife Resources Commission 1722 Mail Service Center Raleigh 27699 NC USA

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National Park Service, Great Smoky Mountains National Park 107 Park Headquarters Road Gatlinburg 37738 TN USA

Publication type: Journal Article

Publication date: 2025-02-19

Wiley

Journal: Journal of Wildlife Management

scimago Q1

SJR: 0.804

CiteScore: 4.0

Impact factor: 1.9

ISSN: 0022541X, 19372817

DOI: 10.1002/jwmg.22733

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Abstract

In an effort to restore extirpated elk to their historical range, 52 elk were reintroduced to Great Smoky Mountains National Park (GRSM) in North Carolina, USA, during 2001 and 2002. Since their reintroduction, elk numbers have increased, and elk have extended their range beyond GRSM boundaries. We used spatially explicit capture‐recapture (SCR) methods based on fecal DNA to identify individual elk and estimate population abundance (N), apparent survival (φ), per capita recruitment (f), and population growth rate (λ) in western North Carolina. We walked a series of transects during 3 winter field seasons (2020–2022) and collected elk pellets encountered along those transects. We created spatially explicit capture histories and incorporated those data into both closed and open population SCR models. The top performing closed SCR models for males and females estimated density by year and as a function of the scaled distance to the nearest field, with densities decreasing as the distance increased. Combined male and female N were 179 elk (95% CI = 149–215) in 2020, 220 elk (95% CI = 188–256) in 2021, and 240 elk (95% CI = 207–279) in 2022. The top open population model estimated both φ and λ as functions of sex and year. The estimate of φ for males was 0.682 (95% CI = 0.317–0.908) during 2020–2021 and 0.339 (95% CI = 0.152–0.596) during 2021–2022 and for females was 0.953 (95% CI = 0.830–1.000) during 2020–2021 and 0.829 (95% CI = 0.601–1.000) during 2021–2022. The annual population growth rate (λ) for males was 1.127 (95% CI = 0.806–1.575) during 2020–2021 and 0.811 (95% CI = 0.566–1.163) during 2021–2022 and for females was 1.559 (95% CI = 1.162–2.091) during 2020–2021 and 1.122 (95% CI = 0.876–1.437) during 2021–2022. Our elk abundance estimates in areas >300 m from fields were negligible, and we suggest that sampling only the areas in and adjacent to fields in the future will result in reliable but more cost‐efficient population estimates. Confidence intervals for vital rate parameters were wide for our 3‐year dataset, but continued annual pellet sampling will increase sample sizes for vital rate estimation and thus improve precision. If elk herd expansion on public lands is desired, we suggest habitat modification to establish open grasslands adjacent to forests.