Spatial resilience of forested landscapes under climate change and management

Lucash, Melissa S.; Scheller, Robert M.; Gustafson, Eric J.; Sturtevant, Brian R.

doi:10.1007/s10980-017-0501-3

Cited by 52 publications

(49 citation statements)

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“…) contained 34 tree species (Table ) at a resolution of 4 ha (Lucash et al. ). The map was a compilation of plot data from the CNF and imputed U.S. Forest Service Forest Inventory and Analysis data (FIA; http://fia.fs.fed.us/) using three maps: two published studies (Wolter et al.…”

Section: Methodsmentioning

confidence: 99%

“…, Lucash et al. ). This extension simulates aboveground and belowground growth of leaves, wood, fine roots, and coarse roots of each cohort on each site at a monthly timestep (Scheller et al.…”

Section: Methodsmentioning

confidence: 99%

“…For example, growth limitation by soil moisture is a function of available water (determined through algorithms of precipitation of snow and rain, evapotranspiration, interception, runoff, and leaching; Lucash et al. ) and a user‐defined curve of how production relates to soil water availability (specified by the extension's predecessor, the CENTURY soil model v 4.5; Parton et al. ).…”

Section: Methodsmentioning

confidence: 99%

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More than the sum of its parts: how disturbance interactions shape forest dynamics under climate change

et al. 2018

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Abstract. Interactions among disturbances are seldom quantified, and how they will be affected by climate change is even more uncertain. In this study, we sought to better understand how interactions among disturbances shift under climate change by applying a process-based landscape disturbance and succession model (LANDIS-II) to project disturbance regimes under climate change in north-central Minnesota, USA. Specifically, we (1) contrasted mortality rates and the extent of disturbance for four individual (single) disturbance regimes (fire, insects, wind, or forest management) vs. all four disturbance regimes operating simultaneously (concurrent) under multiple climate change scenarios and (2) determined how climate change interacts with single and concurrent disturbance regimes to affect carbon stocks and forest composition. Under single disturbance regimes, we found that climate change amplifies mortality, but did not substantially change the overall extent of disturbances. Tree mortality under the concurrent disturbance regime scenario was less than the sum of all single disturbance regimes, providing evidence of significant negative feedbacks among disturbances, particularly under climate change. Finally, we found that climate change was the most critical driver of area harvested (via shifts in species composition), soil carbon, species composition, and diversity, while the disturbance regime (i.e., single or concurrent) had a larger influence on aboveground carbon and the relative dominance of conifers vs. hardwoods. In conclusion, our simulations suggest that disturbance interactions will be strongly mediated by climate change and will produce increasingly negative feedbacks, preventing worst-case disturbance outcomes. Our results underscore the importance of running simulations with multiple disturbances on the landscape concurrently rather than focusing on any one or two disturbances.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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More than the sum of its parts: how disturbance interactions shape forest dynamics under climate change

et al. 2018

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“…❖ www.esajournals.org 4 November 2019 ❖ Volume 10(11) ❖ Article e02934 forest succession and interactions with fire, harvest, wind, and insects (Scheller et al 2008, Duveneck et al 2014, Kretchun et al 2016, Krofcheck et al 2017, Lucash et al 2017. LANDIS-II uses the life-history traits of tree and shrub species, along with soil and climate data, to simulate succession and responses to disturbances over time.…”

Section: Overview Of Simulation Modelmentioning

confidence: 99%

Widespread severe wildfires under climate change lead to increased forest homogeneity in dry mixed‐conifer forests

et al. 2019

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Climate warming in the western United States is causing changes to the wildfire regime in mixed-conifer forests. Rising temperatures, longer fire seasons, increased drought, as well as fire suppression and changes in land use, have led to greater and more severe wildfire activity, all contributing to altered forest composition over the past century. To understand future interactions among climate, wildfire, and vegetation in a fire-prone landscape in the southern Blue Mountains of central Oregon, we used a spatially explicit forest landscape model, LANDIS-II, to simulate forest and fire dynamics under current management practices and two projected climate scenarios. The results suggest that wildfires will become more frequent, more extensive, and more severe under projected climate than contemporary climate. Furthermore, projected climate change generated a 20% increase in the number of extreme fire years (years with at least 40,000 ha burned). This caused large shifts in tree species composition, characterized by a decline in the sub-alpine species (Abies lasiocarpa, Picea engelmannii, Pinus albicaulis) and increases in lowerelevation species (Pinus ponderosa, Abies grandis), resulting in forest homogenization across the elevational gradient. This modeling study suggests that climate-driven increases in fire activity and severity will make high-elevation species vulnerable to decline and will reduce landscape heterogeneity. These results underscore the need for forest managers to actively consider climate change, altered fire regimes, and projected declines in sub-alpine species in their long-term management plans.

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“…In the Amazon rainforest, tree resilience to climate extremes is lower in floodplains than uplands, suggesting that vulnerability to wildfires is responsible for the pattern of spatial resilience (Flores et al, 2017). Forested landscape in north-central Minnesota showed that climate change would reduce resilience (Lucash, Scheller, Gustafson, & Sturtevant, 2017). Forested landscape in north-central Minnesota showed that climate change would reduce resilience (Lucash, Scheller, Gustafson, & Sturtevant, 2017).…”

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Tree resilience to drought increases in the Tibetan Plateau

Fang

Zhang

2018

Global Change Biology

104

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Forests in the Tibetan Plateau are thought to be vulnerable to climate extremes, yet they also tend to exhibit resilience contributing to the maintenance of ecosystem services in and beyond the plateau. So far the spatiotemporal pattern in tree resilience in the Tibetan Plateau remains largely unquantified and the influence of specific factors on the resilience is poorly understood. Here, we study ring‐width data from 849 trees at 28 sites in the Tibetan Plateau with the aim to quantify tree resilience and determine their diving forces. Three extreme drought events in years 1969, 1979, and 1995 are detected from metrological records. Regional tree resistance to the three extreme droughts shows a decreasing trend with the proportion of trees having high resistance ranging from 71.9%, 55.2%, to 39.7%. Regional tree recovery is increasing with the proportion of trees having high recovery ranging from 28.3%, 52.2%, to 64.2%. The area with high resistance is contracting and that of high recovery is expanding. The spatiotemporal resistance and recovery are associated with moisture availability and diurnal temperature range, respectively. In addition, they are both associated with forest internal factor represented by growth consistence among trees. We conclude that juniper trees in the Tibetan Plateau have increased resilience to extreme droughts in the study period. We highlight pervasive resilience in juniper trees. The results have implications for predicting tree resilience and identifying areas vulnerable to future climate extremes.

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Spatial resilience of forested landscapes under climate change and management

Cited by 52 publications

References 47 publications

More than the sum of its parts: how disturbance interactions shape forest dynamics under climate change

More than the sum of its parts: how disturbance interactions shape forest dynamics under climate change

Widespread severe wildfires under climate change lead to increased forest homogeneity in dry mixed‐conifer forests

Tree resilience to drought increases in the Tibetan Plateau

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