Landscape Management Using Historical Fire Regimes: Blue River, Oregon

Cissel, John H.; Swanson, Frederick J.; Weisberg, Peter J.

doi:10.1890/1051-0761(1999)009[1217:lmuhfr]2.0.co;2

Cited by 194 publications

(74 citation statements)

References 23 publications

(23 reference statements)

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“…Fires can increase (or decrease) in severity depending on how much the weighted fuel index of a given cell exceeds (or falls short of) the fuel level thresholds for each fire severity class (T light , T medium , T high , and T max ), and the probability values for the increase or decrease in fire severity (P i and P d ). For example, while the natural fire severity of many stands of the west Cascades can be described as high severity, other stands of the west Cascades have a natural fire severity that can be best described as being of medium severity (;60-80% overstory tree mortality) (Cissel et al 1999). For these stands, medium-severity fires are scheduled to occur throughout the simulated stand and can increase to a high-severity fire depending on the extent to which the weighted fuel index in a cell exceeds the threshold for a high-severity fire, as greater differences between the fuel index and the fire severity threshold will increase the chance of a change in fire severity.…”

Section: Fire Processesmentioning

confidence: 99%

“…For this reason, our experiment incorporated a factorial blocking design where each ecosystem was subjected to four different frequencies of each fuel reduction treatment. We also recognize the fact that fire return intervals can exhibit substantial variation within a single watershed, particularly those with a high degree of topographic complexity (Agee 1993, Cissel et al 1999), so we examined two likely fire regimes for each ecosystem. Historic fire return intervals may become unreliable predictors of future fire intervals (Westerling et al 2006); thus ascertaining the differences in TEC l that result from two fire regimes might be a useful metric in gauging C dynamics resulting from fire regimes that may be further altered as a result of continued global climate change.…”

Section: Experimental Designmentioning

confidence: 99%

“…Bork (1985) estimated a mean fire return interval of 16 years for the east Cascades Pinus ponderosa forests, and we also considered a mean fire return interval of 8 years for this system. Cissel et al (1999) reported mean fire return intervals of 143 and 231 years for forests of medium-and high-severity (standreplacing) fire regimes, respectively, among the Tsuga heterophylla-Pseudotsuga menziesii forests of the west Cascades. Less is known about the fire history of the Coast Range, which consists of Tsuga heterophylla-Pseudotsuga menziesii communities in the interior and Tsuga heterophylla-Picea sitchensis communities occu- pying a narrow edge of land along the Oregon Coast.…”

Section: Experimental Designmentioning

confidence: 99%

See 2 more Smart Citations

Forest fuel reduction alters fire severity and long‐term carbon storage in three Pacific Northwest ecosystems

Mitchell¹,

Harmon

O'Connell

2009

Ecological Applications

135

117

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Two forest management objectives being debated in the context of federally managed landscapes in the U.S. Pacific Northwest involve a perceived trade-off between fire restoration and carbon sequestration. The former strategy would reduce fuel (and therefore C) that has accumulated through a century of fire suppression and exclusion which has led to extreme fire risk in some areas. The latter strategy would manage forests for enhanced C sequestration as a method of reducing atmospheric CO2 and associated threats from global climate change. We explored the trade-off between these two strategies by employing a forest ecosystem simulation model, STANDCARB, to examine the effects of fuel reduction on fire severity and the resulting long-term C dynamics among three Pacific Northwest ecosystems: the east Cascades ponderosa pine forests, the west Cascades western hemlock-Douglas-fir forests, and the Coast Range western hemlock-Sitka spruce forests. Our simulations indicate that fuel reduction treatments in these ecosystems consistently reduced fire severity. However, reducing the fraction by which C is lost in a wildfire requires the removal of a much greater amount of C, since most of the C stored in forest biomass (stem wood, branches, coarse woody debris) remains unconsumed even by high-severity wildfires. For this reason, all of the fuel reduction treatments simulated for the west Cascades and Coast Range ecosystems as well as most of the treatments simulated for the east Cascades resulted in a reduced mean stand C storage. One suggested method of compensating for such losses in C storage is to utilize C harvested in fuel reduction treatments as biofuels. Our analysis indicates that this will not be an effective strategy in the west Cascades and Coast Range over the next 100 years. We suggest that forest management plans aimed solely at ameliorating increases in atmospheric CO2 should forgo fuel reduction treatments in these ecosystems, with the possible exception of some east Cascades ponderosa pine stands with uncharacteristic levels of understory fuel accumulation. Balancing a demand for maximal landscape C storage with the demand for reduced wildfire severity will likely require treatments to be applied strategically throughout the landscape rather than indiscriminately treating all stands.

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Section: Fire Processesmentioning

confidence: 99%

Section: Experimental Designmentioning

confidence: 99%

Section: Experimental Designmentioning

confidence: 99%

See 1 more Smart Citation

Forest fuel reduction alters fire severity and long‐term carbon storage in three Pacific Northwest ecosystems

Mitchell¹,

Harmon

O'Connell

2009

Ecological Applications

135

117

View full text Add to dashboard Cite

show abstract

“…Alternatively, the chronic/partial fire model might offer alternatives to hands-off management in matrix forests. Managers might choose to silviculturally emulate the effects of partial fires through partial cuttings (e.g., thinning and underplanting or green-tree retention), or reintroducing partial fires to create snags and coarse woody debris (Cissel et al 1999) to speed up the creation of old-growth structures. Such active management would require a deliberate choice of fire intensity and the amount and pattern of residual trees, i.e., retaining enough large old overstory Pseudotsuga to garner their life-boating effects, but not too many to preclude the regeneration of shade-intolerants such as Pseudotsuga itself.…”

Section: Management Implicationsmentioning

confidence: 99%

Development of Tree Size Distributions in Douglas‐fir Forests Under Differing Disturbance Regimes

Zenner

2005

Ecological Applications

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Two conceptual models describe the successional and structural development of mature and transitional stands toward old‐growth Pseudotsuga menziesii (Mirbel) Franco forests in the Pacific Northwest. The “catastrophic/maturational” model is based on infrequent catastrophic disturbances that initiate the successional cycle, while the “chronic/ partial fire” model is based on low‐ to moderate‐severity fires which, over long periods of time, can create old‐growth conditions through multiple disturbances. Although both models can produce similar structural characteristics, quantitative differences in speed and pathways of structural development with respect to these models are not well understood. To elucidate these quantitative differences, diameter distributions of live trees were investigated in a chronosequence of mature, transitional, and old‐growth stands subjected to these two disturbance models. Stands characterized by the “catastrophic/maturational” model exhibited varying degrees of rotated sigmoid distributions up to 250–300 years of age because of long establishment periods and differential growth and mortality rates of the component species. They also showed a modest trend toward reverse‐J distributions with increasing stand age. Stands characterized by the “chronic/partial fire” model had a stratum of distinctly older emergent trees with younger cohorts of Pseudotsuga menziesii, Tsuga heterophylla (Raf.) Sarg., and Thuja plicata Donn. and exhibited reverse‐J distributions within about 150–200 years after disturbance. These results suggest that reconsideration of current definitions of what constitutes old‐growth on Tsuga sites may be necessary. A conceptual model is presented, which links pathways of structural development to disturbance regimes. This model indicates that active management can hasten the development of old‐growth structure, even in some older forests.

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“…Landscape pattern analysis based on the patch-matrix model (i.e. landscape pattern indices (LPIs)) or the gradient model (McGarigal et al 2009) has, therefore, received increasing attention in both ecological research and the environmental management communities (Cissel et al 1999, Fu and Chen 2000, Turner 2005). …”

Section: Introductionmentioning

confidence: 99%

Novel shape indices for vector landscape pattern analysis

Zhang

Atkinson

2016

International Journal of Geographical Information Science

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The formation of an anisotropic landscape is influenced by natural and/or human processes, which can then be inferred on the basis of geometric indices. In this study, two minimal bounding rectangles in consideration of the principles of mechanics (i.e. minimal width bounding (MWB) box and moment bounding (MB) box) were introduced. Based on these boxes, four novel shape indices, namely MBLW (the length-to-width ratio of MB box), PAMBA (area ratio between patch and MB box), PPMBP (perimeter ratio between patch and MB box) and ODI (orientation difference index between MB and MWB boxes), were introduced to capture multiple aspects of landscape features including patch elongation, patch compactness, patch roughness and patch symmetry. Landscape pattern was, thus, quantified by considering both patch directionality and patch shape simultaneously, which is especially suitable for anisotropic landscape analysis. The effectiveness of the new indices were tested with real landscape data consisting of three kinds of saline soil patches (i.e. the elongated shaped slightly saline soil class, the circular or half-moon shaped moderately saline soil, and the large and complex severely saline soil patches). The resulting classification was found to be more accurate and robust than that based on traditional shape complexity indices. ARTICLE HISTORY

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Landscape Management Using Historical Fire Regimes: Blue River, Oregon

Cited by 194 publications

References 23 publications

Forest fuel reduction alters fire severity and long‐term carbon storage in three Pacific Northwest ecosystems

Forest fuel reduction alters fire severity and long‐term carbon storage in three Pacific Northwest ecosystems

Development of Tree Size Distributions in Douglas‐fir Forests Under Differing Disturbance Regimes

Novel shape indices for vector landscape pattern analysis

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