Your search keyword '"David Medvigy"' showing total 5 results

1. Focus on tropical dry forest ecosystems and ecosystem services in the face of global change

Author

Jennifer S Powers, Xue Feng, Arturo Sanchez-Azofeifa, and David Medvigy

Subjects

Environmental technology. Sanitary engineering, TD1-1066, Environmental sciences, GE1-350, Science, Physics, QC1-999

Abstract

Tropical dry forests are distinct from wet and moist tropical forests by the presence of a strong dry season. This collection of papers explores the unique biodiversity, plant functional traits, coupling between carbon and water cycles, and threats to these important ecosystems. These studies have relevance for conservation and management of tropical dry forests.

Published

2018

2. Simulated sensitivity of African terrestrial ecosystem photosynthesis to rainfall frequency, intensity, and rainy season length

Author

Kaiyu Guan, Stephen P Good, Kelly K Caylor, David Medvigy, Ming Pan, Eric F Wood, Hisashi Sato, Michela Biasutti, Min Chen, Anders Ahlström, and Xiangtao Xu

Subjects

Africa, water stress, rainfall frequency, rainfall intensity, rainy season length, dynamic vegetation modeling, Environmental technology. Sanitary engineering, TD1-1066, Environmental sciences, GE1-350, Science, Physics, QC1-999

Abstract

There is growing evidence of ongoing changes in the statistics of intra-seasonal rainfall variability over large parts of the world. Changes in annual total rainfall may arise from shifts, either singly or in a combination, of distinctive intra-seasonal characteristics –i.e. rainfall frequency, rainfall intensity, and rainfall seasonality. Understanding how various ecosystems respond to the changes in intra-seasonal rainfall characteristics is critical for predictions of future biome shifts and ecosystem services under climate change, especially for arid and semi-arid ecosystems. Here, we use an advanced dynamic vegetation model (SEIB-DGVM) coupled with a stochastic rainfall/weather simulator to answer the following question: how does the productivity of ecosystems respond to a given percentage change in the total seasonal rainfall that is realized by varying only one of the three rainfall characteristics (rainfall frequency, intensity, and rainy season length)? We conducted ensemble simulations for continental Africa for a realistic range of changes (−20% ~ +20%) in total rainfall amount. We find that the simulated ecosystem productivity (measured by gross primary production, GPP) shows distinctive responses to the intra-seasonal rainfall characteristics. Specifically, increase in rainfall frequency can lead to 28% more GPP increase than the same percentage increase in rainfall intensity; in tropical woodlands, GPP sensitivity to changes in rainy season length is ~4 times larger than to the same percentage changes in rainfall frequency or intensity. In contrast, shifts in the simulated biome distribution are much less sensitive to intra-seasonal rainfall characteristics than they are to total rainfall amount. Our results reveal three major distinctive productivity responses to seasonal rainfall variability—‘chronic water stress’, ‘acute water stress’ and ‘minimum water stress’ - which are respectively associated with three broad spatial patterns of African ecosystem physiognomy, i.e. savannas, woodlands, and tropical forests.

Published

2018

3. Will seasonally dry tropical forests be sensitive or resistant to future changes in rainfall regimes?

Author

Kara Allen, Juan Manuel Dupuy, Maria G Gei, Catherine Hulshof, David Medvigy, Camila Pizano, Beatriz Salgado-Negret, Christina M Smith, Annette Trierweiler, Skip J Van Bloem, Bonnie G Waring, Xiangtao Xu, and Jennifer S Powers

Subjects

climate change, precipitation variability, functional traits, drought, tree phenology, belowground processes, Environmental technology. Sanitary engineering, TD1-1066, Environmental sciences, GE1-350, Science, Physics, QC1-999

Abstract

Seasonally dry tropical forests (SDTF) are located in regions with alternating wet and dry seasons, with dry seasons that last several months or more. By the end of the 21st century, climate models predict substantial changes in rainfall regimes across these regions, but little is known about how individuals, species, and communities in SDTF will cope with the hotter, drier conditions predicted by climate models. In this review, we explore different rainfall scenarios that may result in ecological drought in SDTF through the lens of two alternative hypotheses: 1) these forests will be sensitive to drought because they are already limited by water and close to climatic thresholds, or 2) they will be resistant/resilient to intra- and inter-annual changes in rainfall because they are adapted to predictable, seasonal drought. In our review of literature that spans microbial to ecosystem processes, a majority of the available studies suggests that increasing frequency and intensity of droughts in SDTF will likely alter species distributions and ecosystem processes. Though we conclude that SDTF will be sensitive to altered rainfall regimes, many gaps in the literature remain. Future research should focus on geographically comparative studies and well-replicated drought experiments that can provide empirical evidence to improve simulation models used to forecast SDTF responses to future climate change at coarser spatial and temporal scales.

Published

2017

4. Will seasonally dry tropical forests be sensitive or resistant to future changes in rainfall regimes?

Author

Skip J. Van Bloem, David Medvigy, Catherine M. Hulshof, Bonnie G. Waring, Kara Allen, Christina M. Smith, Juan Manuel Dupuy, Beatriz Salgado-Negret, Camila Pizano, Annette M. Trierweiler, Maria G. Gei, Xiangtao Xu, and Jennifer S. Powers

Subjects

0106 biological sciences, 010504 meteorology & atmospheric sciences, Renewable Energy, Sustainability and the Environment, Simulation modeling, Public Health, Environmental and Occupational Health, Climate change, Forest fragmentation, 010603 evolutionary biology, 01 natural sciences, Deforestation, Climatology, Environmental science, Climate model, Physical geography, 0105 earth and related environmental sciences, General Environmental Science

Abstract

Seasonally dry tropical forests (SDTF) are located in regions with alternating wet and dry seasons, with dry seasons that last several months or more. By the end of the 21st century, climate models predict substantial changes in rainfall regimes across these regions, but little is known about how individuals, species, and communities in SDTF will cope with the hotter, drier conditions predicted by climate models.

Published

2017

5. Simulated impacts of insect defoliation on forest carbon dynamics

Author

Nicholas S. Skowronski, Karina V. R. Schäfer, David Medvigy, and Kenneth L. Clark

Subjects

Biomass (ecology), Pine barrens, Renewable Energy, Sustainability and the Environment, Ecology, Taiga, Public Health, Environmental and Occupational Health, Carbon sink, Atmospheric sciences, Basal area, Carbon cycle, Productivity (ecology), Environmental science, Ecosystem, General Environmental Science

Abstract

Many temperate and boreal forests are subject to insect epidemics. In the eastern US, over 41 million meters squared of tree basal area are thought to be at risk of gypsy moth defoliation. However, the decadal-to-century scale implications of defoliation events for ecosystem carbon dynamics are not well understood. In this study, the effects of defoliation intensity, periodicity and spatial pattern on the carbon cycle are investigated in a set of idealized model simulations. A mechanistic terrestrial biosphere model, ecosystem demography model 2, is driven with observations from a xeric oak‐pine forest located in the New Jersey Pine Barrens. Simulations indicate that net ecosystem productivity (equal to photosynthesis minus respiration) decreases linearly with increasing defoliation intensity. However, because of interactions between defoliation and drought effects, aboveground biomass exhibits a nonlinear decrease with increasing defoliation intensity. The ecosystem responds strongly with both reduced productivity and biomass loss when defoliation periodicity varies from 5 to 15 yr, but exhibits a relatively weak response when defoliation periodicity varies from 15 to 60 yr. Simulations of spatially heterogeneous defoliation resulted in markedly smaller carbon stocks than simulations with spatially homogeneous defoliation. These results show that gypsy moth defoliation has a large effect on oak‐pine forest biomass dynamics, functioning and its capacity to act as a carbon sink.

Published

2012