7 results on '"Atkins, Jeff W."'
Search Results
2. Forest Structural Complexity and Biomass Predict First-Year Carbon Cycling Responses to Disturbance
- Author
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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.
- Published
- 2021
- Full Text
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3. Disturbance‐accelerated succession increases the production of a temperate forest.
- Author
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Gough, Christopher M., Bohrer, Gil, Hardiman, Brady S., Nave, Lucas E., Vogel, Christoph S., Atkins, Jeff W., Bond‐Lamberty, Ben, Fahey, Robert T., Fotis, Alexander T., Grigri, Maxim S., Haber, Lisa T., Ju, Yang, Kleinke, Callie L., Mathes, Kayla C., Nadelhoffer, Knute J., Stuart‐Haëntjens, Ellen, and Curtis, Peter S.
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TEMPERATE forests ,FOREST productivity ,LEAF area index ,DECIDUOUS forests ,RESPIRATION in plants ,SECONDARY forests - Abstract
Many secondary deciduous forests of eastern North America are approaching a transition in which mature early‐successional trees are declining, resulting in an uncertain future for this century‐long carbon (C) sink. We initiated the Forest Accelerated Succession Experiment (FASET) at the University of Michigan Biological Station to examine the patterns and mechanisms underlying forest C cycling following the stem girdling‐induced mortality of >6,700 early‐successional Populus spp. (aspen) and Betula papyrifera (paper birch). Meteorological flux tower‐based C cycling observations from the 33‐ha treatment forest have been paired with those from a nearby unmanipulated forest since 2008. Following over a decade of observations, we revisit our core hypothesis: that net ecosystem production (NEP) would increase following the transition to mid‐late‐successional species dominance due to increased canopy structural complexity. Supporting our hypothesis, NEP was stable, briefly declined, and then increased relative to the control in the decade following disturbance; however, increasing NEP was not associated with rising structural complexity but rather with a rapid 1‐yr recovery of total leaf area index as mid‐late‐successional Acer, Quercus, and Pinus assumed canopy dominance. The transition to mid‐late‐successional species dominance improved carbon‐use efficiency (CUE = NEP/gross primary production) as ecosystem respiration declined. Similar soil respiration rates in control and treatment forests, along with species differences in leaf physiology and the rising relative growth rates of mid‐late‐successional species in the treatment forest, suggest changes in aboveground plant respiration and growth were primarily responsible for increases in NEP. We conclude that deciduous forests transitioning from early to middle succession are capable of sustained or increased NEP, even when experiencing extensive tree mortality. This adds to mounting evidence that aging deciduous forests in the region will function as C sinks for decades to come. [ABSTRACT FROM AUTHOR]
- Published
- 2021
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4. Application of multidimensional structural characterization to detect and describe moderate forest disturbance.
- Author
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ATKINS, JEFF W., BOND-LAMBERTY, BEN, FAHEY, ROBERT T., HABER, LISA T., STUART-HAЁNTJENS, ELLEN, HARDIMAN, BRADY S., LARUE, ELIZABETH, MCNEIL, BRENDEN E., ORWIG, DAVID A., STOVALL, ATTICUS E. L., TALLANT, JASON M., WALTER, JONATHAN A., and GOUGH, CHRISTOPHER M.
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ECOLOGICAL disturbances ,ECOLOGICAL impact ,FOREST canopies ,LIDAR ,PLANT canopies ,REMOTE sensing - Abstract
The study of vegetation community and structural change has been central to ecology for over acentury, yet the ways in which disturbances reshape the physical structure of forest canopies remain relatively unknown. Moderate severity disturbances affect different canopy strata and plant species, resulting in variable structural outcomes and ecological consequences. Terrestrial lidar (light detection and ranging) offers an unprecedented view of the interior arrangement and distribution of canopy elements, permitting the derivation of multidimensional measures of canopy structure that describe several canopy structural traits (CSTs)with known links to ecosystem function. We used lidar-derived CSTs within a machine learning framework to detect and describe the structural changes that result from various disturbance agents, including moderate severity fire, ice storm damage, age-related senescence, hemlock woolly adelgid, beech bark disease, and chronic acidification. We found that fire and ice storms primarily affected the amount and position of vegetation within canopies, while acidification, senescence, pathogen, and insect infestation altered canopy arrangement and complexity. Only two of the six disturbance agents significantly reduced leaf area, counter to common assumptions regarding many moderate severity disturbances. While findings are limited in their generalizability due to lack of replication among disturbances, they do suggest that the current limitations of standard disturbance detection methods—such as optical-based remote sensing platforms, which are often above-canopy perspectives—limit our ability to understand the full ecological and structural impacts of disturbance, and to evaluate the consistency of structural patterns within and among disturbance agents. A more broadly inclusive definition of ecological disturbance that incorporates multiple aspects of canopy structural change may potentially improve the modeling, detection, and prediction of functional implications of moderate severity disturbance as well as broaden our understanding of the ecological impacts of disturbance. [ABSTRACT FROM AUTHOR]
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- 2020
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5. Beech bark disease does not reduce the long-term wood production of two forests contrasting in age, productivity, and structure.
- Author
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Stuart-Haëntjens, Ellen, Atkins, Jeff W., Fotis, Alexander T., Fahey, Robert T., Hardiman, Brady S., Alveshere, Brandon C., Vogel, Christoph, and Gough, Christopher M.
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WOOD ,FOREST productivity ,BEECH ,DECIDUOUS forests ,TREE mortality - Abstract
• We examined the effects of beech bark disease (BBD) on aboveground wood production. • BBD did not reduce production in middle or late successional forest stands. • At the patch-scale, the degree of tree mortality drove changes in production. • Initial responses to BBD sometimes predicted longer-term changes in production. • BBD management should consider scale and the timing of disease progression. The distribution of pests and pathogens is increasing in many forested regions, producing uncertainty for ecological functions, including aboveground wood net primary production (NPP). In North American deciduous forests, beech bark disease (BBD) is restructuring and modifying the composition of forest stands, producing gradients of Fagus grandifolia mortality at finer patch scales. We investigated the multi-decadal effects of BBD on the aboveground wood NPP of a moderately productive middle-successional stand positioned on a glacial outwash plain and a relatively high productivity late-successional stand located on a moraine. Despite average stand-scale basal area losses of ∼ 21% from BBD, aboveground wood NPP increased over time in both the middle- and late- successional stands. At the patch scale, the initial magnitude of change in aboveground wood NPP following BBD infestation correlated with the extent of recovery in the late, but not middle, successional stand, suggesting early responses to disturbance sometimes – but not always – predict long-term production patterns. Patch-scale aboveground wood NPP during different stages of BBD infestation was associated with vegetation quantity and production efficiency, with the latter generally increasing in later stages of the BBD progression. We conclude that the aboveground wood NPP of two forest stands increased through late stages of BBD, despite differences in stand productivity, structure, and age, while patch-scale aboveground wood NPP responses were more variable. [ABSTRACT FROM AUTHOR]
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- 2023
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6. Disturbance has variable effects on the structural complexity of a temperate forest landscape.
- Author
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Gough, Christopher M., Atkins, Jeff W., Fahey, Robert T., Curtis, Peter S., Bohrer, Gil, Hardiman, Brady S., Hickey, Laura J., Nave, Lucas E., Niedermaier, Kerstin M., Clay, Cameron, Tallant, Jason M., and Bond-Lamberty, Ben
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LEAF area index , *TEMPERATE forests , *FOREST resilience , *FOREST dynamics , *STRUCTURAL dynamics - Abstract
• Disturbance effects on forest canopy structural complexity are poorly understood. • We synthesized the results of three forest disturbance manipulations. • Disturbance had variable effects on the temporal dynamics of structural complexity. • Moderate severity disturbance sometimes increased structural complexity. • Disturbance severity, source, and scale constrain temporal changes in complexity. The temporal dynamics of forest canopy structure are influenced by disturbances that alter vegetation quantity and distribution. While canopy structural indicators such as leaf area index (LAI), canopy cover, and canopy height have been widely studied in the context of disturbance, the post-disturbance temporal dynamics of structural complexity, which summarizes the heterogeneity of vegetation arrangement, are poorly understood. With the goal of advancing conceptual and empirical understanding of the temporal dynamics of structural complexity following disturbance, we synthesized results from three large-scale disturbance manipulation experiments at the University of Michigan Biological Station (UMBS): the 4-year Forest Resilience Threshold Experiment (FoRTE) manipulating levels of disturbance severity; the decade-long Forest Accelerated Succession Experiment (FASET), in which all early successional tree species were stem-girdled within 39 ha in the same landscape; and forest chronosequences established following clear-cut harvesting. We found that the temporal dynamics of canopy structure following disturbance were dependent upon three factors: (1) the source and severity of disturbance; (2) the spatial and temporal scales of analysis; and (3) the measure of structure assessed. Unlike vegetation area index and canopy cover, which initially decreased in response to disturbance, structural complexity measures such as canopy and top rugosity did not consistently respond to moderate levels of disturbance severity. Over multi-decadal timescales, structural complexity increased to a maximum, regardless of whether fire occurred at the time of stand establishment, but intervening low-to-moderate severity disturbance in regrown century-old forests altered trajectories of canopy rugosity. We conclude that structural complexity indicators display a more nuanced temporal and directional response to disturbance than conventional leaf area and cover indexes. Predicting what disturbance conditions modify trajectories of structural complexity remains critical to disturbance characterization and the inference of ecosystem functioning. [ABSTRACT FROM AUTHOR]
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- 2022
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7. Aboveground Wood Production Is Sustained in the First Growing Season after Phloem-Disrupting Disturbance.
- Author
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Grigri, Maxim S., Atkins, Jeff W., Vogel, Christoph, Bond-Lamberty, Ben, and Gough, Christopher M.
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GROWING season ,WOOD chemistry ,LEAF area index ,FOREST resilience ,TREE growth ,FORESTS & forestry - Abstract
Carbon (C) cycling processes are particularly dynamic following disturbance, with initial responses often indicative of longer-term change. In northern Michigan, USA, we initiated the Forest Resilience Threshold Experiment (FoRTE) to identify the processes that sustain or lead to the decline of C cycling rates across multiple levels (0, 45, 65 and 85% targeted gross leaf area index loss) of disturbance severity and, in response, to separate disturbance types preferentially targeting large or small diameter trees. Simulating the effects of boring insects, we stem girdled > 3600 trees below diameter at breast height (DBH), immediately and permanently disrupting the phloem. Weekly DBH measurements of girdled and otherwise healthy trees (n > 700) revealed small but significant increases in daily aboveground wood net primary production (ANPP
w ) in the 65 and 85% disturbance severity treatments that emerged six weeks after girdling. However, we observed minimal change in end-of-season leaf area index and no significant differences in annual ANPPw among disturbance severities or between disturbance types, suggesting continued C fixation by girdled trees sustained stand-scale wood production in the first growing season after disturbance. We hypothesized higher disturbance severities would favor the growth of early successional species but observed no significant difference between early and middle to late successional species' contributions to ANPPw across the disturbance severity gradient. We conclude that ANPPw stability immediately following phloem disruption is dependent on the continued, but inevitably temporary, growth of phloem-disrupted trees. Our findings provide insight into the tree-to-ecosystem mechanisms supporting stand-scale wood production stability in the first growing season following a phloem-disrupting disturbance. [ABSTRACT FROM AUTHOR]- Published
- 2020
- Full Text
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