Homogenization of northern U.S. Great Lakes forests due to land use

Schulte, Lisa A.; Mladenoff, David J.; Crow, Thomas R.; Merrick, Laura C.; Cleland, David

doi:10.4016/5368.01

Cited by 38 publications

(68 citation statements)

References 18 publications

(31 reference statements)

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“…Alterations of disturbance regimes in concert with habitat degradation can lead to a loss of ecosystem diversity. There is growing evidence for the homogenization of northern Great Lakes forests via conifer loss (Frelich & Lorimer, 1985;Rhemtulla et al, 2007;Schulte et al, 2007;Nowacki & Abrams, 2008). Northern Wisconsin forests were historically dominated by conifer and mixed conifer-hardwood stands (Schulte et al, 2007).…”

Section: Introductionmentioning

confidence: 99%

“…There is growing evidence for the homogenization of northern Great Lakes forests via conifer loss (Frelich & Lorimer, 1985;Rhemtulla et al, 2007;Schulte et al, 2007;Nowacki & Abrams, 2008). Northern Wisconsin forests were historically dominated by conifer and mixed conifer-hardwood stands (Schulte et al, 2007). Because of intense deforestation and resultant fires after Euro-American settlement, old growth forest types decreased in abundance and were replaced by early successional forest types (Rhemtulla et al, 2007).…”

Section: Introductionmentioning

confidence: 99%

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Converging forest community composition along an edaphic gradient threatens landscape‐level diversity

Amatangelo

Fulton

Rogers

et al. 2010

Diversity and Distributions

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Aim Plant communities across the temperate zone are changing in response to successional processes and human‐induced disturbances. Here, we assess how upland forest under‐ and overstorey community composition has changed along an edaphic gradient. Location Northern Wisconsin, USA. Methods Forest sites initially sampled in the 1950s were resampled for overstorey composition and diversity, basal area, and understorey composition and diversity. We used clustering methods to identify groups of stands based on overstorey composition, and we used similarity indices, ordination and diversity indices to evaluate changes in species abundance and overall community structure. Results Sites clustered into four overstorey groups along the edaphic gradient: ‘hemlock’ sites dominated by hemlock in 1950, ‘mesic’ sites dominated by northern hardwoods, ‘dry’ sites with a significant pine inclusion in the canopy and diverse ‘dry‐mesic’ sites in the middle. Collectively, forests gained maple, ash and cherry while losing pines, birches and red oaks. The hemlock forest sites gained hardwoods, while the dry‐mesic sites shifted towards a more mesic hardwood composition. Only the driest sites have remained relatively stable in species composition. Main conclusions These trends reflect both ‘mesification’ and homogenization among northern forests. Highly diverse mid‐gradient and mesic hemlock‐dominated stands are transitioning to maple dominance. Fire suppression may be favouring invasions of more mesic plants into historically drier sites, while high deer abundance likely limits hemlock regeneration. If current trends continue, maples will dominate the majority of northern forests, with significant losses of local native species richness and substantial shifts in understorey composition.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Converging forest community composition along an edaphic gradient threatens landscape‐level diversity

Amatangelo

Fulton

Rogers

et al. 2010

Diversity and Distributions

View full text Add to dashboard Cite

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“…Once the Cutover had cleared large swaths of these forests, the logging industry waned, resulting in a mass migration of workers from the region that would not revive until the post-WWII planting of successional forests for recreation, wise use, and restoration (Rhemtulla et al 2009). Today, as a result of post-Depression-era public land designations in the 1940s, forestry and restoration have resulted in a patchwork of homogenous coniferous and deciduous stands (Radeloff et al 1999, Schulte et al 2007.…”

Section: Study Area and Historymentioning

confidence: 99%

“…Biomass-weighted estimates of forest composition are based on Public Land Survey System (PLSS) records (Schulte et al 2007, Liu et al 2011, Goring et al 2016, Cogbill et al 2018 and United States Forest Service Forest Inventory and Analysis (FIA) data (Forest Inventory Analysis Program 2007, Gray et al 2012). PLSS records provide an estimate of mid-to late-1800s forests, while FIA observations are from the most recent full plot inventory (2007)(2008)(2009)(2010)(2011) (Goring et al 2016).…”

Section: Forestry Datamentioning

confidence: 99%

Land‐use and climatic causes of environmental novelty in Wisconsin since 1890

Williams

Burke

Crossley

et al. 2019

Ecological Applications

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Multiple global change drivers are increasing the present and future novelty of environments and ecological communities. However, most assessments of environmental novelty have focused only on future climate and were conducted at scales too broad to be useful for land management or conservation. Here, using historical county‐level data sets of agricultural land use, forest composition, and climate, we conduct a regional‐scale assessment of environmental novelty for Wisconsin landscapes from ca. 1890 to 2012. Agricultural land‐use data include six cropland types, livestock densities for four livestock species, and human populations. Forestry data comprise biomass‐weighted relative abundances for 15 tree genera. Climate data comprise seasonal means for temperature and precipitation. We found that forestry and land use are the strongest cause of environmental novelty (NoveltyForest = 3.66, NoveltyAg = 2.83, NoveltyClimate = 1.60, with Wisconsin's forests transformed by early 20th‐century logging and its legacies and multiple waves of agricultural innovation and obsolescence. Climate change is the smallest contributor to contemporary novelty, with precipitation signals stronger than temperature. Magnitudes and causes of environmental novelty are strongly spatially patterned, with novelty in southern Wisconsin roughly twice that in northern Wisconsin. Forestry is the most important cause of novelty in the north, land use and climate change are jointly important in the southwestern Wisconsin, and land use and forest composition are most important in central and eastern Wisconsin. Areas of high regional novelty tend also to be areas of high local change, but local change has not pushed all counties beyond regional baselines. Seven counties serve as the best historical analogues for over one‐half of contemporary Wisconsin counties (40/72), and so can offer useful historical counterparts for contemporary systems and help managers coordinate to tackle similar environmental challenges. Multi‐dimensional environmental novelty analyses, like those presented here, can help identify the best historical analogues for contemporary ecosystems, places where new management rules and practices may be needed because novelty is already high, and the main causes of novelty. Separating regional novelty clearly from local change and measuring both across many dimensions and at multiple scales thus helps advance ecology and sustainability science alike.

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“…In a region close to the present study, Ziter et al (2014) found that carbon storage was robust to both management and edge effects (but see Isbell et al (2015)). However, the homogenizing effects of forest management and use on community composition (Schulte et al, 2007;Thompson et al, 2013) might eliminate or reduce the relative abundance of species that can contribute to the provisioning of other vital ecosystem functions, including nutrient cycling, pollination or seed dispersal, and associated ecosystem services (Mitchell et al, 2014). It can also affect the ability of the ecosystem to resist or adapt to unknown disturbances such as forest pests and pathogens (Boyd et al, 2013) or invasion by alien plant species (Tanentzap et al, 2010) that could negatively affect the dominant species.…”

Section: Ecological Resilience and Functional Composition Across Privmentioning

confidence: 99%

Evaluating resilience of tree communities in fragmented landscapes: linking functional response diversity with landscape connectivity

Craven

Filotas²,

Angers

et al. 2016

Diversity and Distributions

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These authors contributed equally to this work.ABSTRACT Aim Multiple agents of change increasingly impact functioning of forest ecosystems, for which management plans often ignore how local disturbances and habitat fragmentation jointly operate on ecological resilience at different scales. We examined sensitivity of functional response diversity (FD) to variation in species diversity to predict ecological resilience to future disturbances across tree communities and evaluated the role of landscape connectivity in maintaining ecological resilience at the landscape scale.Location Centre-du-Quebec, Quebec, Canada.Methods We inventoried private forests and calculated FD and communityweighted means to determine the extent to which forest-use intensity affects ecological resilience. Subsequently, we constructed a regional map of FD, from which a spatial network was extracted. To assess potential impacts of fragmentation in maintaining FD at the landscape scale, we examined how the functional connectivity of the landscape, measured by the probability of connectivity (PC), varied across a range of maximum seed dispersal distances. Lastly, we evaluated the importance of individual forest fragments in maintaining landscape FD by measuring the connectivity fractions of PC.Results Across tree communities, ecological resilience was low as FD increased sharply with species diversity. Forests with high FD were dominated by species with trait values associated with greater resilience to future anthropogenic disturbances rather than to future climate change. FD was maintained across the landscape by forest fragments acting as intermediate stepping stones in the transfer of seeds.Main conclusions We employed a novel approach based on spatial networks to extend the functional diversity concept from the local to the landscape scale. Our results suggest that seed dispersal over sufficiently large distances can maintain ecological resilience in fragmented landscapes and buffer changes in local-scale FD. Otherwise, FD is maintained by local processes, meaning that ecological resilience of isolated forest fragments depends strongly on land use type and intensity.

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Homogenization of northern U.S. Great Lakes forests due to land use

Cited by 38 publications

References 18 publications

Converging forest community composition along an edaphic gradient threatens landscape‐level diversity

Converging forest community composition along an edaphic gradient threatens landscape‐level diversity

Land‐use and climatic causes of environmental novelty in Wisconsin since 1890

Evaluating resilience of tree communities in fragmented landscapes: linking functional response diversity with landscape connectivity

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