Your search keyword '"Goheen, J.R."' showing total 5 results

1. Reciprocity in restoration ecology: When might large carnivore reintroduction restore ecosystems?

Author

Alston, J.M., Maitland, B.M., Brito, B.T., Esmaeili, S., Ford, A.T., Hays, B., Jesmer, B.R., Molina, F.J., and Goheen, J.R.

Published

2019

2. Evaluating expert-based habitat suitability information of terrestrial mammals with GPS-tracking data

Author

Broekman, M.J.E., Hilbers, J.P., Huijbregts, M.A.J., Mueller, T., Ali, A.H., Andren, H., Altmann, J., Aronsson, M., Attias, N., Bartlam-Brooks, H.L.A., van Beest, F.M., Belant, J.L., Beyer, D.E., Bidner, L., Blaum, N., Boone, R.B., Boyce, M.S., Brown, M.B., Cagnacci, F., Cerne, R., Chamaille-Jammes, S., Dejid, N., Dekker, J., Desbiez, A.L.J., Diaz-Munoz, S.L., Fennessy, J., Fichtel, C., Fischer, C., Fisher, J.T., Fischhoff, I, Ford, A.T., Fryxell, J.M., Gehr, B., Goheen, J.R., Hauptfleisch, M., Hewison, A.J.M., Hering, R., Heurich, M., Isbell, L.A., Janssen, R., Jeltsch, F., Kaczensky, P., Kappeler, P.M., Krofel, M., LaPoint, S., Latham, A.D.M., Linnell, J.D.C., Markham, A.C., Mattisson, J., Medici, E.P., de Miranda Mourao, G., Van Moorter, B., Morato, R.G., Morellet, N., Mysterud, A., Ndambuki, S., Odden, J., Olson, K.A., Ornicans, A., Pagon, N., Panzacchi, M., Persson, J., Petroelje, T., Rolandsen, C.M., Roshier, D., Rubenstein, D.I., Said, S., Salemgareyev, A.R., Sawyer, H., Schmidt, N.M., Selva, N., Sergiel, A., Stabach, J., Stacy-Dawes, J., Stewart, F.E.C., Stiegler, J., Strand, O., Sundaresan, S., Svoboda, N.J., Ullmann, W., Voigt, U., Wall, J., Wikelski, M., Wilmers, C.C., Zieba, F., Zwijacz-Kozica, T., Schipper, A.M., Tucker, M.A., Broekman, M.J.E., Hilbers, J.P., Huijbregts, M.A.J., Mueller, T., Ali, A.H., Andren, H., Altmann, J., Aronsson, M., Attias, N., Bartlam-Brooks, H.L.A., van Beest, F.M., Belant, J.L., Beyer, D.E., Bidner, L., Blaum, N., Boone, R.B., Boyce, M.S., Brown, M.B., Cagnacci, F., Cerne, R., Chamaille-Jammes, S., Dejid, N., Dekker, J., Desbiez, A.L.J., Diaz-Munoz, S.L., Fennessy, J., Fichtel, C., Fischer, C., Fisher, J.T., Fischhoff, I, Ford, A.T., Fryxell, J.M., Gehr, B., Goheen, J.R., Hauptfleisch, M., Hewison, A.J.M., Hering, R., Heurich, M., Isbell, L.A., Janssen, R., Jeltsch, F., Kaczensky, P., Kappeler, P.M., Krofel, M., LaPoint, S., Latham, A.D.M., Linnell, J.D.C., Markham, A.C., Mattisson, J., Medici, E.P., de Miranda Mourao, G., Van Moorter, B., Morato, R.G., Morellet, N., Mysterud, A., Ndambuki, S., Odden, J., Olson, K.A., Ornicans, A., Pagon, N., Panzacchi, M., Persson, J., Petroelje, T., Rolandsen, C.M., Roshier, D., Rubenstein, D.I., Said, S., Salemgareyev, A.R., Sawyer, H., Schmidt, N.M., Selva, N., Sergiel, A., Stabach, J., Stacy-Dawes, J., Stewart, F.E.C., Stiegler, J., Strand, O., Sundaresan, S., Svoboda, N.J., Ullmann, W., Voigt, U., Wall, J., Wikelski, M., Wilmers, C.C., Zieba, F., Zwijacz-Kozica, T., Schipper, A.M., and Tucker, M.A.

Abstract

17 juni 2022, Contains fulltext : 252380.pdf (Publisher’s version ) (Open Access), In our paper "Evaluating expert-based habitat suitability information of terrestrial mammals with GPS-tracking data" (Global Ecology and Biogeography) we use GPS tracking data from 1,498 from 49 different species to evaluate the expert-based habitat suitability data from the International Union for Conservation of Nature (IUCN). Therefore, we used the GPS tracking data to estimate two measures of habitat suitability for each individual animal and habitat type: proportional habitat use (proportion of GPS locations within a habitat type), and selection ratio (habitat use relative to its availability). For each individual we then evaluated whether the GPS-based habitat suitability measures were in agreement with the IUCN data. To that end, we calculated the probability that the ranking of empirical habitat suitability measures was in agreement with IUCN’s classification into suitable, marginal and unsuitable habitat types. Our results showed that IUCN habitat suitability data were in accordance with the GPS data (>95% probability of agreement) for 33 out of 49 species based on proportional habitat use estimates and for 25 out of 49 species based on selection ratios. In addition, 37 and 34 species had a >50% probability of agreement based on proportional habitat use and selection ratios, respectively. These findings indicate that for the majority of species included in this study, it is appropriate to use IUCN habitat suitability data in macroecological studies. Furthermore, our study shows that GPS tracking data can be used to identify and prioritize species and habitat types for re-evaluation of IUCN habitat suitability data. In this dataset we provide the measures of habitat suitability for each individual and each habitat type, calculated using different methods. In addition, we provide data on the body mass and IUCN Red List category of the species, as well as whether the species can be considered a habitat specialist or habitat generalist.

Published

2022

3. Environmental drivers of body size in North American bats

Author

Alston, J.M., primary, Keinath, D.A., additional, Willis, C.K.R., additional, Lausen, C.L., additional, O’Keefe, J.M., additional, Tyburec, J.D., additional, Broders, H.G., additional, Moosman, P.R., additional, Carter, T.C., additional, Chambers, C.L., additional, Gillam, E.H., additional, Geluso, K., additional, Weller, T.J, additional, Burles, D.W., additional, Fletcher, Q.E., additional, Norquay, K.J.O., additional, and Goheen, J.R., additional

Published

2021

4. Effects of body size on estimation of mammalian area requirements

Author

Noonan, M.J., Fleming, C.H., Tucker, M.A., Kays, R., Harrison, A.L., Crofoot, M.C., Abrahms, B., Alberts, S.C., Ali, A.H., Altmann, J., Antunes, P.C., Attias, N., Belant, J.L., Beyer, D.E., Jr., Bidner, L.R., Blaum, N., Boone, R.B., Caillaud, D., Paula, R.C. de, Torre, J.A. de la, Dekker, J., DePerno, C.S., Farhadinia, M., Fennessy, J., Fichtel, C., Fischer, C., Ford, A., Goheen, J.R., Havmoller, R.W., Hirsch, B.T., Hurtado, C., Isbell, L.A., Janssen, Rene, Jeltsch, F., Kaczensky, P., Kaneko, Y., Kappeler, P., Katna, A., Kauffman, M., Koch, F., Kulkarni, A., LaPoint, S., Leimgruber, P., Macdonald, D.W., Markham, A.C., McMahon, L., Mertes, K., Moorman, C.E., Morato, R.G., Mossbrucker, A.M., Mourao, G., O'Connor, D., Oliveira-Santos, L.G.R., Pastorini, J., Patterson, B.D., Rachlow, J., Ranglack, D.H., Reid, N., Scantlebury, D.M., Scott, D.M., Selva, N., Sergiel, A., Songer, M., Songsasen, N., Stabach, J.A., Stacy-Dawes, J., Swingen, M.B., Thompson, J.J., Ullmann, W., Vanak, A.T., Thaker, M., Wilson, J.W., Yamazaki, K., Yarnell, R.W., Zieba, F., Zwijacz-Kozica, T., Fagan, W.F., Mueller, T., Calabrese, J.M., Noonan, M.J., Fleming, C.H., Tucker, M.A., Kays, R., Harrison, A.L., Crofoot, M.C., Abrahms, B., Alberts, S.C., Ali, A.H., Altmann, J., Antunes, P.C., Attias, N., Belant, J.L., Beyer, D.E., Jr., Bidner, L.R., Blaum, N., Boone, R.B., Caillaud, D., Paula, R.C. de, Torre, J.A. de la, Dekker, J., DePerno, C.S., Farhadinia, M., Fennessy, J., Fichtel, C., Fischer, C., Ford, A., Goheen, J.R., Havmoller, R.W., Hirsch, B.T., Hurtado, C., Isbell, L.A., Janssen, Rene, Jeltsch, F., Kaczensky, P., Kaneko, Y., Kappeler, P., Katna, A., Kauffman, M., Koch, F., Kulkarni, A., LaPoint, S., Leimgruber, P., Macdonald, D.W., Markham, A.C., McMahon, L., Mertes, K., Moorman, C.E., Morato, R.G., Mossbrucker, A.M., Mourao, G., O'Connor, D., Oliveira-Santos, L.G.R., Pastorini, J., Patterson, B.D., Rachlow, J., Ranglack, D.H., Reid, N., Scantlebury, D.M., Scott, D.M., Selva, N., Sergiel, A., Songer, M., Songsasen, N., Stabach, J.A., Stacy-Dawes, J., Swingen, M.B., Thompson, J.J., Ullmann, W., Vanak, A.T., Thaker, M., Wilson, J.W., Yamazaki, K., Yarnell, R.W., Zieba, F., Zwijacz-Kozica, T., Fagan, W.F., Mueller, T., and Calabrese, J.M.

Abstract

Contains fulltext : 226766.pdf (publisher's version ) (Open Access)

Published

2020

5. Experimental removal of strong and weak predators: mice and chipmunks preying on songbird nests

Author

Schmidt, K.A., Goheen, J.R., Naumann, R., Ostfeld, R.S., Schauber, E.M., and Berkowitz, Alan

Subjects

Ecological research -- Reports, Predation (Biology) -- Environmental aspects, Birds -- Environmental aspects, Mice -- Environmental aspects, Chipmunks -- Environmental aspects, Biological sciences, Environmental issues

Abstract

We examined the effects of separate removal experiments of two generalist consumers, the white-footed mouse (Peromyscus leucopus) and the eastern chipmunk (Tamias striatus), on nest predation rates of forest songbirds. Mice are numerically dominant at our study sites and were shown to be strong predators in other predator-prey interactions, such as those involving gypsy moths. Therefore, we hypothesized that removal of mice would result in decreased levels of nest predation relative to control treatments with a complete predator assemblage, but that the removal of chipmunks would not result in decreased nest predation. Both hypotheses were supported. Mice depredated >60% of artificial nests in control plots (mouse populations intact), whereas chipmunks depredated ~20%. Daily nest mortality rates in mouse removal treatments were less than half the rates in controls but were virtually identical between chipmunk removal and control treatments. Nonetheless, when we examined predation rates across plots in which the density of mice varied naturally, total daily mortality rates declined as the density of mice increased. This pattern occurred because mortality from non-mouse predators decreased as the density of mice increased and overwhelmed increasing mortality from mice to drive the overall dynamics of the system. Analysis of the relationships between the density of mice and predation rates by mice as a function of the abundance of natural food in their environment revealed probable reasons for these conflicting results. We suggest that high local densities of mice deplete resources for larger, non-mouse predators, which preferentially occupy areas of few mice and high local food abundance. In these areas, songbirds may be faced with higher overall nest predation dominated by non-mouse predators. Mice thus influence nest predation rates through both direct and indirect pathways. Key words: indirect interactions; nest predation; Peromyscus; predator compensation; songbirds; strong interactions; Tamias; white-footed mouse.

Published

2001