Aquatic Ecosystem Response to Timber Harvesting for the Purpose of Restoring Aspen

Jones, Bobette E.; Krupa, Monika; Tate, Kenneth W.

doi:10.1371/journal.pone.0084561

Cited by 5 publications

(3 citation statements)

References 84 publications

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“…The average age for the harvested forests in this study followed the trend west > south > north (Tables 2–5), and studies have shown the importance of age of forest materials on decomposition rates (Troendle et al, 2010; Jones et al, 2013). Mature conifer forests have also been reported to use more water than mature aspen forests, leading to less nutrient export (Jones et al, 2013).…”

Section: Resultssupporting

confidence: 56%

“…The average age for the harvested forests in this study followed the trend west > south > north (Tables 2-5), and studies have shown the importance of age of forest materials on decomposition rates (Troendle et al, 2010;Jones et al, 2013). Mature conifer forests have also been reported to use more water than mature aspen forests, leading to less nutrient export ( Jones et al, 2013). Stream flow response was also reported to be affected by species composition and the percentage change in vegetation density in the western region (Troendle et al, 2010), and in the eastern coastal plain ( Jayakaran et al, 2014), with a potential to affect nutrient and sediment exports.…”

Section: Effects Of Plant Species Distributionsupporting

confidence: 57%

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Regional Differences in Stream Water Nitrogen, Phosphorus, and Sediment Responses to Forest Harvesting in the Conterminous USA

Muwamba

Rau²,

Trettin

et al. 2019

J of Env Quality

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Forest harvesting and management techniques were hypothesized to result in significant differences in stream water N (NO3–N), P (total P [TP]), and total suspended sediment (TSS) responses among regions of United States. The objectives were (i) to determine the mean response periods after harvesting for each water quality variable, (ii) to compare the regional response yields, and (iii) to determine relationships among water quality, rainfall, and flow. Watershed‐scale studies where best management practices were implemented provided a basis for water quality analyses. A mixed model was used to estimate the time from harvest to time when the harvested site yielded similar export as the reference site (response period). Normalized water quality yields were calculated as response yields (kg ha−1 yr−1) times estimated response periods. Significant differences among yields were identified using ANOVA and Tukey test (α = 0.05), and relationships between water quality and hydrologic variables were identified using multivariate analysis (α = 0.05). The ratio of estimated mean response period for TSS to NO3–N and TP, each individually, was approximately two. The mean normalized NO3–N response yield was greater for the northern than the southern and/or western regions. Normalized NO3–N and TSS response yields were greater for plantations than for other harvest types. The TSS export significantly increased with discharge from plantations. The literature‐based response periods used in this study were not fully monitored, and soil surface manipulations after harvesting pose a significant influence on sediment export in the United States. Core Ideas Publications on water quality responses to US forest harvesting were explored. The mean response period after harvesting for total suspended sediments (TSS) was 8.8 yr. The mean response period for NO3–N and total P were 4.3 and 3.9 yr, respectively. The greatest NO3–N response was 265.2 kg ha−1 for plantations in the northern region. The greatest TSS response was 17,756.6 kg ha−1 for plantations in the southern region.

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Section: Resultssupporting

confidence: 56%

Section: Effects Of Plant Species Distributionsupporting

confidence: 57%

Regional Differences in Stream Water Nitrogen, Phosphorus, and Sediment Responses to Forest Harvesting in the Conterminous USA

Muwamba

Rau²,

Trettin

et al. 2019

J of Env Quality

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show abstract

“…For example, the Washington State Department of Natural Resources outlines riparian management strategies to restore conifer dominated riparian areas (Bigley and Deisenhofer, 2006). Additional studies in Lassen National Forest seek to restore aspen stands for habitat and ecosystem services (Jones et al, 2013). Furthermore, there has been documented success at releasing suppressed conifers in riparian areas using patch cutting and thinning in parts of Oregon (Emmingham et al, 2000;Maas-Hebner et al, 2005).…”

Section: Riparian Vegetation Conversionmentioning

confidence: 99%

Effects of Streamside Buffers on Stream Temperatures Associated With Forest Management and Harvesting Using DHSVM-RBM; South Fork Caspar Creek, California

Ridgeway

Surfleet

2021

Front. For. Glob. Change

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Forest harvesting has been shown to effect water quantity and water quality parameters, highlighting the need for comprehensive forest practice rules. Being able to understand and predict these impacts on stream temperature is especially critical where federally threatened or endangered fish species are located. The goal of this research was to predict responses in stream temperature to potential riparian and forest harvest treatments in a maritime, mountainous environment. The Distributed Hydrology Soil Vegetation Model (DHSVM) and River Basin Model (RBM) were calibrated to measured streamflow and stream temperatures in the South Fork of the Caspar Creek Experimental Watersheds during critical summer periods when temperatures are highest and flows are low for hydrologic years 2010–2016. The modeling scenarios evaluated were (1) varying percentages of stream buffer canopy cover, (2) a harvest plan involving incrementally reduced stand densities in gauged sub-watersheds, and (3) an experimental design converting dominant riparian vegetation along set reaches. The model predicted a noticeable rise in stream temperatures beginning when stream buffer canopy cover was reduced to 25 and 0% retention levels. Larger increases in Maximum Weekly Maximum Temperatures (MWMT), compared to Maximum Weekly Average Temperatures (MWAT), occurred across all scenarios. There was essentially no difference in MWAT or MWMT between altering buffers along only fish bearing (Class I) watercourses and altering buffers along all watercourses. For the scenario with stream buffers at 0% retention, MWMTs consistently rose above recommended thermal limits for coho salmon (Oncorhynchus kisutch). Predictions when clearcutting the entire watershed showed less of an effect than simulations with 0% buffer retention, suggesting groundwater inflows mitigate stream temperature rises in the South Fork. The harvest simulation showed a small but consistent increase in MWATs (avg. 0.11°C), and more varied increases in MWMTs (avg. 0.32°C). Sensitivity analyses suggest potentially unrealistic tracking of downstream temperatures, making the vegetation conversion simulations inconclusive. Additional sensitivity analyses suggest tree height and monthly extinction coefficient (a function of leaf area index) were most influential on temperatures in the South Fork, which was consistent with other modeling studies suggesting management focus on tall, dense buffers compared to wider buffer widths.

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The effects of forest management on water quality

Shah

Baillie²,

Bishop

et al. 2022

Forest Ecology and Management

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Aquatic Ecosystem Response to Timber Harvesting for the Purpose of Restoring Aspen

Cited by 5 publications

References 84 publications

Regional Differences in Stream Water Nitrogen, Phosphorus, and Sediment Responses to Forest Harvesting in the Conterminous USA

Regional Differences in Stream Water Nitrogen, Phosphorus, and Sediment Responses to Forest Harvesting in the Conterminous USA

Effects of Streamside Buffers on Stream Temperatures Associated With Forest Management and Harvesting Using DHSVM-RBM; South Fork Caspar Creek, California

The effects of forest management on water quality

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