Your search keyword '"Fahey, Robert T."' showing total 7 results

1. NEON-SD: A 30-m Structural Diversity Product Derived from the NEON Discrete-Return LiDAR Point Cloud.

Author

Wang, Jianmin, Choi, Dennis H., LaRue, Elizabeth, Atkins, Jeff W., Foster, Jane R., Matthes, Jaclyn H., Fahey, Robert T., Fei, Songlin, and Hardiman, Brady S.

Subjects

POINT cloud, LANDSAT satellites, LIDAR, SPATIAL resolution, ELEVATING platforms

Abstract

Structural diversity (SD) characterizes the volume and physical arrangement of biotic components in an ecosystem which control critical ecosystem functions and processes. LiDAR data provides detailed 3-D spatial position information of components and has been widely used to calculate SD. However, the intensive computation of SD metrics from extensive LiDAR datasets is time-consuming and challenging for researchers who lack access to high-performance computing resources. Moreover, a lack of understanding of LiDAR data and algorithms could lead to inconsistent SD metrics. Here, we developed a SD product using the Discrete-Return LiDAR Point Cloud from the NEON Aerial Observation Platform. This product provides SD metrics detailing height, density, openness, and complexity at a spatial resolution of 30 m, aligned to the Landsat grids, for 211 site-years for 45 Terrestrial NEON sites from 2013 to 2022. To accommodate various ecosystems with different understory heights, it includes three different cut-off heights (0.5 m, 2 m, and 5 m). This structural diversity product can enable various applications such as ecosystem productivity estimation and disturbance monitoring. [ABSTRACT FROM AUTHOR]

Published

2024

2. Conceptualizing social-ecological drivers of change in urban forest patches.

Author

Johnson, Lea R., Johnson, Michelle L., Aronson, Myla F. J., Campbell, Lindsay K., Carr, Megan E., Clarke, Mysha, D'Amico, Vincent, Darling, Lindsay, Erker, Tedward, Fahey, Robert T., King, Kristen L., Lautar, Katherine, Locke, Dexter H., Morzillo, Anita T., Pincetl, Stephanie, Rhodes, Luke, Schmit, John Paul, Scott, Lydia, and Sonti, Nancy F.

Subjects

FOREST management, TEMPERATE forests, CITY dwellers, FOREST health, CONCEPTUAL models, FOREST biodiversity

Abstract

We introduce a conceptual model of the urban forest patch as a complex social-ecological system, incorporating cross-scale interactions. We developed this model through an interdisciplinary process engaging social and ecological scientists and urban land management decision makers, with a focus on temperate forest social-ecological systems. In this paper, we place the production and management of urban forest patches in historical perspective, present a conceptual model of urban forest patches within a broader regional context, and identify a series of research questions to highlight future directions for research on urban forest patches. This conceptual model identifies how spatial and temporal social-ecological drivers interact with patch-level conditions at multiple scales. Our integrative approach can provide insights into the role of social-ecological drivers in shaping forest health, biodiversity, and benefits forest patches provide to people in urban and urbanizing regions, with direct implications for decision-making to improve management outcomes. [ABSTRACT FROM AUTHOR]

Published

2021

3. Forest Structural Complexity and Biomass Predict First-Year Carbon Cycling Responses to Disturbance.

Author

Gough, Christopher M., Atkins, Jeff W., Bond-Lamberty, Ben, Agee, Elizabeth A., Dorheim, Kalyn R., Fahey, Robert T., Grigri, Maxim S., Haber, Lisa T., Mathes, Kayla C., Pennington, Stephanie C., Shiklomanov, Alexey N., and Tallant, Jason M.

Subjects

CARBON cycle, BIOMASS, LEAF area index, SOIL respiration, FOREST resilience, WOODY plants

Abstract

The pre-disturbance vegetation characteristics that predict carbon (C) cycling responses to disturbance are not well known. To address this gap, we initiated the Forest Resilience Threshold Experiment, a manipulative study in which more than 3600 trees were stem girdled to achieve replicated factorial combinations of four levels (control, 45, 65, and 85% gross defoliation) of disturbance severity and two disturbance types (targeting upper or lower canopy strata). Applying a standardized stability framework in which initial C cycling resistance to disturbance was calculated as the first-year natural log response ratio of disturbance and control treatments, we investigated to what extent pre-disturbance levels of species diversity, aboveground woody biomass, leaf area index, and canopy rugosity—a measure of structural complexity—predict the initial responses of subcanopy light-saturated leaf CO2 assimilation (Asat), aboveground wood NPP (ANPPw), and soil respiration (Rs) to phloem-disrupting disturbance. In the year following stem girdling, we found that above-ground C cycling processes, Asat and ANPPw, were highly resistant to increases in disturbance severity, while Rs resistance declined as severity increased. Disturbance type had no effect on first-year resistance. Pre-disturbance aboveground woody biomass, and canopy rugosity were positive predictors of ANPPw resistance and, conversely, negatively related to Rs resistance. Subcanopy Asat resistance was not related to pre-disturbance vegetation characteristics. Stability of C uptake processes along with Rs declines suggest the net C sink was sustained in the initial months following disturbance. We conclude that biomass and complexity are significant, but not universal, predictors of initial C cycling resistance to disturbance. Moreover, our findings highlight the utility of standardized stability measures when comparing functional responses to disturbance. [ABSTRACT FROM AUTHOR]

Published

2021

4. Ecosystem Nitrogen Response to a Simulated Ice Storm in a Northern Hardwood Forest.

Author

Weitzman, Julie N., Groffman, Peter M., Campbell, John L., Driscoll, Charles T., Fahey, Robert T., Fahey, Timothy J., Schaberg, Paul G., and Rustad, Lindsey E.

Subjects

HARDWOOD forests, NITROGEN cycle, ICE storms, GLOBAL environmental change, FOREST canopies, ECOLOGICAL disturbances

Abstract

Ice storms are important but understudied disturbances that influence forest structure and function. In 1998, an ice storm damaged forest canopies and led to increased hydrologic losses of nitrogen (N) from the northern hardwood forest at the Hubbard Brook Experimental Forest (HBEF), a Long-Term Ecological Research (LTER) site in New Hampshire, USA. To evaluate the mechanisms underlying this response, we experimentally simulated ice storms with different frequencies and severities at the small plot scale. We took measurements of plant and soil variables before (2015) and after (2016, 2017) treatments using the same methods used in 1998 with a focus on hydrologic and gaseous losses of reactive N, as well as rates of soil N cycle processes. Nitrogen cycle responses to the treatments were insignificant and less marked than the responses to the 1998 natural ice storm. Pools and leaching of inorganic N, net and gross mineralization and nitrification and denitrification rates, and soil to atmosphere fluxes of nitrous oxide (N2O) were unaffected by the treatments, in contrast to the 1998 storm which caused marked increases in leaching and watershed export of inorganic N. The difference in response may be a manifestation of N oligotrophication that has occurred at the HBEF over the past 30 years. Results suggest that ecosystem response to disturbances, such as ice storms, is changing due to aspects of global environmental change, challenging our ability to understand and predict the effects of these events on ecosystem structure, function, and services. [ABSTRACT FROM AUTHOR]

Published

2020

5. Effects of canopy structure and species diversity on primary production in upper Great Lakes forests.

Author

Scheuermann, Cynthia M., Nave, Lucas E., Fahey, Robert T., Nadelhoffer, Knute J., and Gough, Christopher M.

Subjects

PLANT species diversity, PLANT canopies, LEAF area index, SOIL chronosequences, CLIMATE change

Abstract

Canopy structure and tree species diversity, shaped by succession, disturbance, and community composition, are linked to numerous ecosystem functions, including net primary production (NPP). Understanding of how ecosystem structural metrics are interrelated and mechanistically link to NPP, however, is incomplete. We characterized leaf area index (LAI), Simpson’s index of Diversity (D′, a measure of species diversity), and canopy rugosity (Rc, a measure of canopy physical complexity) in 11 forest stands comprising two chronosequences varying in establishing disturbance, and in three late successional communities. We related LAI, D′, and Rc to wood NPP (NPPw), and examined whether absorption of photosynthetically active radiation and light use-efficiency (LUE) link NPPw with ecosystem structure. We found that recovery of LAI and D′ was delayed following more severe establishing disturbances, but that the development of Rc was strikingly conserved regardless of disturbance, converging on a common mean value in late-successional stands irrespective of differences in leaf area index and species diversity. LAI was significantly correlated with NPPw in each stage of ecosystem development, but NPPw was only correlated with Rc in early successional stages and with D′ in late successional stages. Across all stands, NPPw was coupled with LAI and Rc, (but not D′) through positive relationships with light absorption and LUE. We conclude by advocating for better integration of ecological disciplines investigating structure-function interactions, suggesting that improved understanding of such relationships will require ecologists to traverse disciplinary boundaries. [ABSTRACT FROM AUTHOR]

Published

2018

6. Variation in urban forest productivity and response to extreme drought across a large metropolitan region.

Author

Bialecki, Margaret B., Fahey, Robert T., and Scharenbroch, Bryant

Subjects

URBAN forestry, ARBORICULTURE, CLIMATOLOGY, DROUGHTS, PLANT growth

Abstract

The growth and survival of urban trees and maintenance of urban forest canopy are important considerations in adaptation of urban regions to climate change, especially in relation to increasing frequency of extreme climatic events such as drought. However, urban forest growth and drought response may vary considerably within large urban landscapes across gradients in land use, urbanization, forest composition and structure, and environmental factors. We quantified urban forest growth and resilience and resistance to extreme drought in the greater Chicago metropolitan region based on patterns of annual basal area production from increment core analysis. We evaluated variation in growth and drought response in relation to a broad urban to rural gradient, land-use categories, local-scale environmental predictors, and forest community characteristics. Urban forest growth varied greatly among land-use classes and major genera. Plot-level variation in productivity was predicted most strongly (R2 = 0.53) by total plot-level basal area, canopy height, species composition, soil and ground-cover characteristics, and position within the urban-rural gradient. Urban forest growth was strongly related to regional meteorological drought. In periods of extreme drought conditions growth declined in the year of the drought (i.e., was not resistant to drought effects), but was highly resilient to drought in the subsequent 5 year period. Drought response did not vary consistently across land-use classes or among major genera, and site or community characteristics had little explanatory power in predicting drought response. Improved understanding of factors driving variation in urban forest growth and drought response could help inform adaptation-focused urban forest management strategies. [ABSTRACT FROM AUTHOR]

Published

2018

7. Ecosystem Consequences of Exotic Earthworm Invasion of North Temperate Forests.

Author

Bohlen, Patrick J., Groffman, Peter M., Fahey, Timothy J., Fisk, Melany C., Suárez, Esteban, Pelletier, Derek M., and Fahey, Robert T.

Subjects

PLANT invasions, BIOLOGICAL invasions, INTRODUCED species, CARBON, NITROGEN, PHOSPHORUS, PLANT roots, NUTRIENT cycles, FORESTS & forestry

Abstract

The invasion of north temperate forests by exotic species of earthworms is an important issue that has been overlooked in the study and management of these forests. We initiated research to address the hypothesis that earthworm invasion will have large consequences for nutrient retention and uptake in these ecosystems. In this special feature of Ecosystems, we present five papers describing results from our experiment. In this paper, we (a) introduce our experimental approach and conceptual model of how earthworms influence forest ecosystem processes, (b) describe the characteristics of the study areas and earthworm communities at our two study locations, and (c) provide a brief overview and synthesis of the main findings. The most dramatic effect of earthworm invasion was the loss of the forest floor at an undisturbed forest site, which altered the location and nature of nutrient cycling activity in the soil profile. Invasion changed soil total carbon (C) and phosphorus (P) pools, carbon—nitrogen (C:N) ratios, the loss and distribution of different soil P fractions, and the distribution and function of roots and microbes. Response to invasion varied with site characteristics and earthworm species. Our results suggest that exotic earthworm invasion is a significant factor that will influence the structure and function of northern temperate forest ecosystems over the next few decades. Regional evaluations of these forests will need to consider the presence or absence of earthworms along with other important ecosystem drivers, such as pollution, climate, and underlying soil characteristics. [ABSTRACT FROM AUTHOR]

Published

2004