Alternative community states maintained by fire in the Klamath Mountains, USA

Odion, Dennis C.; Moritz, Max A.; DellaSala, Dominick A.

doi:10.1111/j.1365-2745.2009.01597.x

Cited by 178 publications

(206 citation statements)

References 85 publications

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“…Thus, varying amplitudes of interannual-todecadal-scale climatic variability (e.g., El Niño Southern Oscillation) could have a major impact on the prevalence of fire climate in our study area (16). Episodic fire patterns also may be promoted by fire-vegetation feedbacks if vegetation switches among alternate stable states (shrublands versus forest) with different levels of pyrogenicity (3). Unfortunately, the open-shrub vegetation types (e.g., Quercus) are poorly represented in the USL pollen record and cannot help test this hypothesis.…”

Section: Resultsmentioning

confidence: 98%

“…historical fire | climate variability | ecological resilience | logging | sediment charcoal F ire plays a key role structuring ecosystems of the floristically diverse Siskiyou and Klamath Mountains of southwest Oregon and Northwest California (1,2), driving successional pathways (3) and affecting the erosion rate of soils (4,5). Fire-history data obtained from tree-ring records suggest that before Euro-American settlement forests supported a mixed-severity fire regime characterized by minor amounts of stand-replacing high-severity fire (6)(7)(8).…”

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confidence: 99%

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Highly episodic fire and erosion regime over the past 2,000 y in the Siskiyou Mountains, Oregon

Colombaroli

Gavin

2010

Proc. Natl. Acad. Sci. U.S.A.

120

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Fire is a primary mode of natural disturbance in the forests of the Pacific Northwest. Increased fuel loads following fire suppression and the occurrence of several large and severe fires have led to the perception that in many areas there is a greatly increased risk of high-severity fire compared with presettlement forests. To reconstruct the variability of the fire regime in the Siskiyou Mountains, Oregon, we analyzed a 10-m, 2,000-y sediment core for charcoal, pollen, and sedimentological data. The record reveals a highly episodic pattern of fire in which 77% of the 68 charcoal peaks before Euro-American settlement cluster within nine distinct periods marked by a 15-y mean interval. The 11 largest charcoal peaks are significantly related to decadal-scale drought periods and are followed by pulses of minerogenic sediment suggestive of rapid sediment delivery. After logging in the 1950s, sediment load was increased fourfold compared with that from the most severe presettlement fire. Less severe fires, marked by smaller charcoal peaks and no sediment pulses, are not correlated significantly with drought periods. Pollen indicators of closed forests are consistent with fire-free periods of sufficient length to maintain dense forest and indicate a fire-triggered switch to more open conditions during the Medieval Climatic Anomaly. Our results indicate that over millennia fire was more episodic than revealed by nearby shorter tree-ring records and that recent severe fires have precedents during earlier drought episodes but also that sediment loads resulting from logging and road building have no precedent in earlier fire events.historical fire | climate variability | ecological resilience | logging | sediment charcoal

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Section: Resultsmentioning

confidence: 98%

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confidence: 99%

Highly episodic fire and erosion regime over the past 2,000 y in the Siskiyou Mountains, Oregon

Colombaroli

Gavin

2010

Proc. Natl. Acad. Sci. U.S.A.

120

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“…No two landscapes were alike. Variation in landscape patterns of physiognomic types too created unique fire regime interactions between types (Lauvaux et al, 2016;Odion et al, 2010). For example, in landscapes with mixed forest and grassland/shrubland conditions, grass-fire/ shrub-fire cycles were often influential to adjacent forest fire frequency and severity.…”

Section: Recent Changes In Msforestsmentioning

confidence: 99%

“…Varying patterns of physiognomic conditions (sparse woodland, pre-forest, forest, herbland, and shrubland) are also clearly apparent in most historical MSForests as a consequence of disturbance frequency and intensity, and climatic influences (Hessburg et al, 1999a(Hessburg et al, , 1999bLenihan et al, 2003;Maxwell et al, 2014;Millar et al, 2007;Neilson, 1986Neilson, , 1995. For example, historically it was common for some MSForest settings to remain for a time in alternate woodland, shrubland, or grassland states due to relatively high fire frequency, coupled with occasional high-severity fire (Beisner et al, 2003;Odion et al, 2010). But with a warming climate creating conditions for more high-severity fire (Westerling et al, 2003;Lenihan et al, 2006), and the occurrence of larger and more frequent high-severity burned areas (Miller et al, , 2012Harris and Taylor, 2015), there is now a greater potential for severely burned patches to be converted to these alternative stable states (Lauvaux et al, 2016;Long et al, 2014a;Harris and Taylor, 2015;Perry et al, 2011;Savage and Mast, 2005).…”

Section: Re-creating and Protecting Meso-scale Heterogeneitymentioning

confidence: 99%

Tamm Review: Management of mixed-severity fire regime forests in Oregon, Washington, and Northern California

Hessburg

Spies

Perry

et al. 2016

Forest Ecology and Management

170

189

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a b s t r a c tIncreasingly, objectives for forests with moderate-or mixed-severity fire regimes are to restore successionally diverse landscapes that are resistant and resilient to current and future stressors. Maintaining native species and characteristic processes requires this successional diversity, but methods to achieve it are poorly explained in the literature. In the Inland Pacific US, large, old, early seral trees were a key historical feature of many young and old forest successional patches, especially where fires frequently occurred. Large, old trees are naturally fire-tolerant, but today are often threatened by dense understory cohorts that create fuel ladders that alter likely post-fire successional pathways. Reducing these understories can contribute to resistance by creating conditions where canopy trees will survive disturbances and climatic stressors; these survivors are important seed sources, soil protectors, and critical habitat elements. Historical timber harvesting has skewed tree size and age class distributions, created hard edges, and altered native patch sizes. Manipulating these altered forests to promote development of larger patches of older, larger, and more widely-spaced trees with diverse understories will increase landscape resistance to severe fires, and enhance wildlife habitat for underrepresented conditions.Closed-canopy, multi-layered patches that develop in hot, dry summer environments are vulnerable to droughts, and they increase landscape vulnerability to insect outbreaks and severe wildfires. These same patches provide habitat for species such as the northern spotted owl, which has benefited from increased habitat area. Regional and local planning will be critical for gauging risks, evaluating trade-offs, and restoring dynamics that can support these and other species. The goal will be to manage for heterogeneous landscapes that include variably-sized patches of (1) young, middle-aged, and old, closedcanopy forests growing in upper montane, northerly aspect, and valley bottom settings, (2) a similar diversity of open-canopy, fire-tolerant patches growing on ridgetops, southerly aspects, and lower montane settings, and (3) significant montane chaparral and grassland areas. Tools to achieve this goal http://dx

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“…Reference conditions are also used as a source of information for identifying restoration goals and the types of treatment that might be used in places where contemporary forest conditions are approaching a bounded range of variation (Moritz et al 2013) or have moved outside their historical range of variability (Morgan et al 1994, White and Walker 1997, Swetnam et al 1999, Taylor 2004, Larson and Churchill 2012, Wiens et al 2012. Presumably, moving highly altered forests towards conditions within the historical range of variability should increase their resilience to wildfire and reduce the risk of unexpected outcomes such as vegetation type conversions caused by unusually severe wildfire related to high fuel loads from logging and or fire exclusion (Weatherspoon and Skinner 1996, Landres et al 1999, Savage and Mast 2005, Odion et al 2010. Consequently, identifying reference conditions is a key step in the ecosystem managementrestoration planning process but it is a particularly challenging task in locations where most if not all of the pre-settlement forests have been removed by logging and other types of human activity (Landres et al 1999, Swetnam et al 1999, Scholl and Taylor 2010, Wiens et al 2012.…”

Section: Introductionmentioning

confidence: 99%

Landscape‐scale modeling of reference period forest conditions and fire behavior on heavily logged lands

et al. 2014

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Landscape-scale modeling of reference period forest conditions and fire behavior on heavily logged lands. Ecosphere 5(3):32. http://dx.doi.org/10.1890/ES13-00294.1Abstract. Forest conditions prior to extensive land clearing are often used as a point-of-reference by ecologists and resource managers for characterizing the historical range of variability in forest conditions shaped by intact disturbance regimes. Quantitative data on forest reference conditions can be developed from forest surveys and reconstructions using dendroecology; however, these methods lack the spatial resolution needed for landscape management. In this paper, we combine predictive vegetation mapping methods with reference forest conditions inferred from early forest surveys, dendroecology, and fire simulation models to develop landscape-scale reference conditions for forest structure, forest fuels, fire frequency, and fire behavior using the Lake Tahoe Basin, California as an example.The dendroecological reconstruction method used for the Lake Tahoe Basin forests was not sensitive to variation in decomposition rates suggesting that our method provided robust estimates of reference period forest characteristics. The cluster analysis procedure identified five forest structure types (white fir, Jeffrey pine, red fir, lodgepole pine, and subalpine) and 15 subtypes. Each forest type had a characteristic composition, density, and basal area. Our random forests approach to classifying and mapping the spatial distribution of the five dominant reference forest structure types resulted in 51.5% classification accuracy using 14 physiographic and climatic variables. The random forests model to identify subtypes within each forest group had an average percent correct classification of 47.8%. The random forests model for fire intervals explained 67% of the variance in the point fire return interval estimates from fire-scarred trees. Estimates of reference period fuels modeled from stand structure suggested moderate fuel loads for reference forests. The predicted potential fire type for forest subtypes under extreme weather was surface fire except for red fir and the lodgepole pine subtypes with potential for crown fire. By characterizing the reference forest composition, structure, and disturbance frequency with a range of variability, managers can develop a forested landscape more resilient to changes in disturbance regime and climate. Although our approach was developed for the Lake Tahoe Basin, California, it could be applied to a wide range of forest landscapes to identify forest reference conditions.

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Alternative community states maintained by fire in the Klamath Mountains, USA

Cited by 178 publications

References 85 publications

Highly episodic fire and erosion regime over the past 2,000 y in the Siskiyou Mountains, Oregon

Highly episodic fire and erosion regime over the past 2,000 y in the Siskiyou Mountains, Oregon

Tamm Review: Management of mixed-severity fire regime forests in Oregon, Washington, and Northern California

Landscape‐scale modeling of reference period forest conditions and fire behavior on heavily logged lands

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