Andrea Pearce

Name:

Andrea Pearce

Role:

Faculty Associate

Address:

School of Engineering,University of Vermont

Burlington, VT 05405

United States

Email:

arpearce@uvm.edu

Recent Publications

Pearce, Andrea R, Edward B Rastetter, Bonnie L Kwiatkowski, William B Bowden, Michelle C Mack, and Yueyang Jiang. 2015. “Recovery Of Arctic Tundra From Thermal Erosion Disturbance Is Constrained By Nutrient Accumulation: A Modeling Analysis”. Ecological Applications 25 (5). Ecological Applications: 1271-1289. doi:10.1890/14-1323.1.

Jiang, Yueyang, Edward B Rastetter, Adrian V Rocha, Andrea R Pearce, Bonnie L Kwiatkowski, and Gaius R Shaver. 2015. “Modeling Carbon–Nutrient Interactions During The Early Recovery Of Tundra After Fire”. Ecological Applications 25 (6). Ecological Applications: 1640 - 1652. doi:10.1890/14-1921.1.

Bowden, William B, Julia R Larouche, Andrea R Pearce, B. T Crosby, K. Krieger, M. B Flinn, J. R Kampman, et al.. 2012. “An Integrated Assessment Of The Influences Of Upland Thermal-Erosional Features On Landscape Structure And Function In The Foothills Of The Brooks Range, Alaska”. Proceedings Of The Tenth International Conference On Permafrost. Proceedings Of The Tenth International Conference On Permafrost. Salekhard, Yamal-Nenets Autonomous District, Russia.

All Publications for Andrea R. Pearce

Data Sets

Long term response of arctic tussock tundra to thermal erosion features: A modeling analysis. Tussock tundra regrowth after a thermal erosion event: Simulation G - increased P deposition

Long term response of arctic tussock tundra to thermal erosion features: A modeling analysis. Tussock tundra regrowth after a thermal erosion event: Simulation A - increased Phase II soil organic matter

Long term response of arctic tussock tundra to thermal erosion features: A modeling analysis. Undisturbed tussock tundra

Long term response of arctic tussock tundra to thermal erosion features: A modeling analysis. Tussock tundra regrowth after a thermal erosion event: Simulation I - doubled Phase I decomposition

Long term response of arctic tussock tundra to thermal erosion features: A modeling analysis. Tussock tundra regrowth after a thermal erosion event: Simulation J - doubled Phase II decomposition

Long term response of arctic tussock tundra to thermal erosion features: A modeling analysis. Tussock tundra regrowth after a thermal erosion event: Simulation H - increased N and P deposition

Long term response of arctic tussock tundra to thermal erosion features: A modeling analysis. Tussock tundra regrowth after a thermal erosion event: Simulation B - increased Phase I soil organic matter

Long term response of arctic tussock tundra to thermal erosion features: A modeling analysis. Tussock tundra recovery after a thermal erosion event

Long term response of arctic tussock tundra to thermal erosion features: A modeling analysis. Tussock tundra regrowth after a thermal erosion event: Simulation F - increased N deposition

Long term response of arctic tussock tundra to thermal erosion features: A modeling analysis. Tussock tundra regrowth after a thermal erosion event: Simulation D - reduced Phase I and Phase II soil organic matter

Long term response of arctic tussock tundra to thermal erosion features: A modeling analysis. Tussock tundra recovery after a thermal erosion event: saturating nutrients.

Long term response of arctic tussock tundra to thermal erosion features: A modeling analysis. Tussock tundra regrowth after a thermal erosion event: Simulation C - increased Phase I and Phase II soil organic matter

Long term response of arctic tussock tundra to thermal erosion features: A modeling analysis. Tussock tundra regrowth after a thermal erosion event: Simulation E - reduced Phase I soil organic matter

Long term response of arctic tussock tundra to thermal erosion features: A modeling analysis. A 100 yr old thermal erosion event under control conditions.

Long term response of arctic tussock tundra to thermal erosion features: A modeling analysis. Tussock tundra greenhouse simulation