Evan Grant, Ph.D.
Evan Grant the principle investigator of the US Geological Survey’s Amphibian Research and Monitoring Initiative (ARMI), northeast region.
Evan's research focuses on questions relating to amphibian populations, specifically with respect to their landscape-scale ecology. Evan also uses decision science to aid resource managers.
Education:
- PhD, 2009, University of Maryland College Park, Program of Marine, Estuarine and Environmental Sciences and Department of Entomology
- BS, 2001, Cornell University, Natural Resources, with Distinction in Research
ResearcherID: N-5160-2014
Research Gate profile: http://www.researchgate.net/profile/Evan_Grant2
Science and Products
A comparison of monitoring designs to assess wildlife community parameters across spatial scales
Looking ahead, guided by the past: The role of U.S. national parks in amphibian research and conservation
Summary and synthesis of 15 years of the Amphibian Vital Sign monitoring in the National Capital Region Inventory and Monitoring Network
Site- and individual-level contaminations affect infection prevalence of an emerging infectious disease of amphibians
Geographic variation and thermal plasticity shape salamander metabolic rates under current and future climates
Evaluating the effect of expert elicitation techniques on population status assessment in the face of large uncertainty
Identifying climate-resistant vernal pools: Hydrologic refugia for amphibian reproduction under droughts and climate change
Experimental evaluation of spatial capture–recapture study design
Rapid assessment indicates context-dependent mitigation for amphibian disease risk
Evaluation of regulatory action and surveillance as preventive risk-mitigation to an emerging global amphibian pathogen Batrachochytrium salamandrivorans (Bsal)
Metal accumulation varies with life history, size, and development of larval amphibians
Risks posed by SARS‐CoV‐2 to North American bats during winter fieldwork
The virus that causes COVID‐19 likely evolved in a mammalian host, possibly Old‐World bats, before adapting to humans, raising the question of whether reverse zoonotic transmission to bats is possible. Wildlife management agencies in North America are concerned that the activities they authorize could lead to transmission of SARS‐CoV‐2 to bats from humans. A rapid risk assessment conducted in Apri
Science and Products
A comparison of monitoring designs to assess wildlife community parameters across spatial scales
Looking ahead, guided by the past: The role of U.S. national parks in amphibian research and conservation
Summary and synthesis of 15 years of the Amphibian Vital Sign monitoring in the National Capital Region Inventory and Monitoring Network
Site- and individual-level contaminations affect infection prevalence of an emerging infectious disease of amphibians
Geographic variation and thermal plasticity shape salamander metabolic rates under current and future climates
Evaluating the effect of expert elicitation techniques on population status assessment in the face of large uncertainty
Identifying climate-resistant vernal pools: Hydrologic refugia for amphibian reproduction under droughts and climate change
Experimental evaluation of spatial capture–recapture study design
Rapid assessment indicates context-dependent mitigation for amphibian disease risk
Evaluation of regulatory action and surveillance as preventive risk-mitigation to an emerging global amphibian pathogen Batrachochytrium salamandrivorans (Bsal)
Metal accumulation varies with life history, size, and development of larval amphibians
Risks posed by SARS‐CoV‐2 to North American bats during winter fieldwork
The virus that causes COVID‐19 likely evolved in a mammalian host, possibly Old‐World bats, before adapting to humans, raising the question of whether reverse zoonotic transmission to bats is possible. Wildlife management agencies in North America are concerned that the activities they authorize could lead to transmission of SARS‐CoV‐2 to bats from humans. A rapid risk assessment conducted in Apri