Mark Haroldson
Mark Haroldson is an emeritus USGS Wildlife Biologist for the Interagency Grizzly Bears Study Team and works out of the Northern Rocky Mountain Science Center, Bozeman, MT.
Research Interest
Mark has had a passion for bears since he began studying them as an undergraduate in 1976. He has worked in bear research and management in several western states ever since. Since 1984 he has worked in various capacities for the Interagency Grizzly Bear Study Team in the Greater Yellowstone Ecosystem. Current research is focused on mortality and population trend of grizzly bears in the Greater Yellowstone Ecosystem.
Education and Certifications
B.S. Wildlife Biology, 1979, University of Montana
Graduate level class work, 1982-88, University of Montana
Science and Products
Filter Total Items: 91
Omnivory and the terrestrial food web: Yellowstone grizzly beard diets Omnivory and the terrestrial food web: Yellowstone grizzly beard diets
No abstract available.
Authors
Charles C. Schwartz, Mark A. Haroldson, Kerry A. Gunther, Charles T. Robbins
Body and diet composition of sympatric black and grizzly bears in the Greater Yellowstone Ecosystem Body and diet composition of sympatric black and grizzly bears in the Greater Yellowstone Ecosystem
The Greater Yellowstone Ecosystem (GYE) has experienced changes in the distribution and availability of grizzly bear (Ursus arctos) food resources in recent decades. The decline of ungulates, fish, and whitebark pine seeds (Pinus albicaulis) has prompted questions regarding their ability to adapt. We examined body composition and diet of grizzly bears using bioelectrical impedance and...
Authors
Charles C. Schwartz, Jennifer K. Fortin, Justin E. Teisberg, Mark A. Haroldson, Christopher Servheen, Charles T. Robbins, Frank T. van Manen
Grizzly bear population vital rates and trend in the Northern Continental Divide Ecosystem, Montana Grizzly bear population vital rates and trend in the Northern Continental Divide Ecosystem, Montana
We estimated grizzly bear (Ursus arctos) population vital rates and trend for the Northern Continental Divide Ecosystem (NCDE), Montana, between 2004 and 2009 by following radio-collared females and observing their fate and reproductive performance. Our estimates of dependent cub and yearling survival were 0.612 (95% CI = 0.300–0.818) and 0.682 (95% CI = 0.258–0.898). Our estimates of...
Authors
R.D. Mace, D.W. Carney, T. Chilton-Radandt, S.A. Courville, M.A. Haroldson, R.B. Harris, J. Jonkel, B. McLellan, M. Madel, T.L. Manley, C.C. Schwartz, C. Servheen, G. Stenhouse, J.S. Waller, E. Wenum
Population fragmentation and inter-ecosystem movements of grizzly bears in Western Canada and the Northern United States Population fragmentation and inter-ecosystem movements of grizzly bears in Western Canada and the Northern United States
Population fragmentation compromises population viability, reduces a species ability to respond to climate change, and ultimately may reduce biodiversity. We studied the current state and potential causes of fragmentation in grizzly bears over approximately 1,000,000 km 2 of western Canada, the northern United States (US), and southeast Alaska. We compiled much of our data from projects
Authors
M.F. Proctor, David Paetkau, B. N. McLellan, G.B. Stenhouse, K.C. Kendall, R.D. Mace, W.F. Kasworm, C. Servheen, C.L. Lausen, M.L. Gibeau, W.L. Wakkinen, M.A. Haroldson, G. Mowat, C.D. Apps, L.M. Ciarniello, R.M.R. Barclay, M.S. Boyce, C.C. Schwartz, C. Strobeck
Impacts of rural development on Yellowstone wildlife: linking grizzly bear Ursus arctos demographics with projected residential growth Impacts of rural development on Yellowstone wildlife: linking grizzly bear Ursus arctos demographics with projected residential growth
Exurban development is consuming wildlife habitat within the Greater Yellowstone Ecosystem with potential consequences to the long-term conservation of grizzly bears Ursus arctos. We assessed the impacts of alternative future land-use scenarios by linking an existing regression-based simulation model predicting rural development with a spatially explicit model that predicted bear...
Authors
Charles C. Schwartz, Patricia H. Gude, Lisa Landenburger, Mark A. Haroldson, Shannon Podruzny
Study design and sampling intensity for demographic analyses of bear populations Study design and sampling intensity for demographic analyses of bear populations
The rate of population change through time (??) is a fundamental element of a wildlife population's conservation status, yet estimating it with acceptable precision for bears is difficult. For studies that follow known (usually marked) bears, ?? can be estimated during some defined time by applying either life-table or matrix projection methods to estimates of individual vital rates...
Authors
R.B. Harris, C.C. Schwartz, R.D. Mace, M.A. Haroldson
Science and Products
Filter Total Items: 91
Omnivory and the terrestrial food web: Yellowstone grizzly beard diets Omnivory and the terrestrial food web: Yellowstone grizzly beard diets
No abstract available.
Authors
Charles C. Schwartz, Mark A. Haroldson, Kerry A. Gunther, Charles T. Robbins
Body and diet composition of sympatric black and grizzly bears in the Greater Yellowstone Ecosystem Body and diet composition of sympatric black and grizzly bears in the Greater Yellowstone Ecosystem
The Greater Yellowstone Ecosystem (GYE) has experienced changes in the distribution and availability of grizzly bear (Ursus arctos) food resources in recent decades. The decline of ungulates, fish, and whitebark pine seeds (Pinus albicaulis) has prompted questions regarding their ability to adapt. We examined body composition and diet of grizzly bears using bioelectrical impedance and...
Authors
Charles C. Schwartz, Jennifer K. Fortin, Justin E. Teisberg, Mark A. Haroldson, Christopher Servheen, Charles T. Robbins, Frank T. van Manen
Grizzly bear population vital rates and trend in the Northern Continental Divide Ecosystem, Montana Grizzly bear population vital rates and trend in the Northern Continental Divide Ecosystem, Montana
We estimated grizzly bear (Ursus arctos) population vital rates and trend for the Northern Continental Divide Ecosystem (NCDE), Montana, between 2004 and 2009 by following radio-collared females and observing their fate and reproductive performance. Our estimates of dependent cub and yearling survival were 0.612 (95% CI = 0.300–0.818) and 0.682 (95% CI = 0.258–0.898). Our estimates of...
Authors
R.D. Mace, D.W. Carney, T. Chilton-Radandt, S.A. Courville, M.A. Haroldson, R.B. Harris, J. Jonkel, B. McLellan, M. Madel, T.L. Manley, C.C. Schwartz, C. Servheen, G. Stenhouse, J.S. Waller, E. Wenum
Population fragmentation and inter-ecosystem movements of grizzly bears in Western Canada and the Northern United States Population fragmentation and inter-ecosystem movements of grizzly bears in Western Canada and the Northern United States
Population fragmentation compromises population viability, reduces a species ability to respond to climate change, and ultimately may reduce biodiversity. We studied the current state and potential causes of fragmentation in grizzly bears over approximately 1,000,000 km 2 of western Canada, the northern United States (US), and southeast Alaska. We compiled much of our data from projects
Authors
M.F. Proctor, David Paetkau, B. N. McLellan, G.B. Stenhouse, K.C. Kendall, R.D. Mace, W.F. Kasworm, C. Servheen, C.L. Lausen, M.L. Gibeau, W.L. Wakkinen, M.A. Haroldson, G. Mowat, C.D. Apps, L.M. Ciarniello, R.M.R. Barclay, M.S. Boyce, C.C. Schwartz, C. Strobeck
Impacts of rural development on Yellowstone wildlife: linking grizzly bear Ursus arctos demographics with projected residential growth Impacts of rural development on Yellowstone wildlife: linking grizzly bear Ursus arctos demographics with projected residential growth
Exurban development is consuming wildlife habitat within the Greater Yellowstone Ecosystem with potential consequences to the long-term conservation of grizzly bears Ursus arctos. We assessed the impacts of alternative future land-use scenarios by linking an existing regression-based simulation model predicting rural development with a spatially explicit model that predicted bear...
Authors
Charles C. Schwartz, Patricia H. Gude, Lisa Landenburger, Mark A. Haroldson, Shannon Podruzny
Study design and sampling intensity for demographic analyses of bear populations Study design and sampling intensity for demographic analyses of bear populations
The rate of population change through time (??) is a fundamental element of a wildlife population's conservation status, yet estimating it with acceptable precision for bears is difficult. For studies that follow known (usually marked) bears, ?? can be estimated during some defined time by applying either life-table or matrix projection methods to estimates of individual vital rates...
Authors
R.B. Harris, C.C. Schwartz, R.D. Mace, M.A. Haroldson