Logging impacts on the biogeochemistry of boreal forest soils and nutrient export to aquatic systems: A review

Kreutzweiser, David P.; Hazlett, P. W.; Gunn, John M.

doi:10.1139/a08-006

Cited by 278 publications

(278 citation statements)

References 168 publications

(189 reference statements)

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“…Possibly clear-cutting increase stream water nutrient concentrations less in northern than in southern Fennoscandia due to slower mineralization rates and lower deposition fluxes (Akselsson et al 2004;Kortelainen et al 2006;Futter et al 2010;Palviainen et al 2014), and in the northern catchments the observed rise in nutrient loading is largely due to the increased runoff (Ahtiainen and Huttunen 1999;Palviainen et al 2014). The increase in total N, NO 3 -N, NH 4 -N and PO 4 -P concentrations after clear-cutting is in accordance with the results from other boreal catchments (Grip 1982;Rosén et al 1996;Lamontagne et al 2000;Kreutzweiser et al 2008). The increases in the concentrations of N fractions in stream water could result from higher deposition loads due to the lack of N retention by tree canopy (Piirainen et al 2002), reduced nutrient uptake by trees and understory vegetation (Palviainen et al 2007), and increased nitrification in litter layer and soil (Paavolainen and Smolander 1998).…”

Section: Specific Concentrationssupporting

confidence: 85%

“…The magnitude and duration of the changes in concentrations depend on several factors such as catchment topography, soil properties, site fertility, atmospheric deposition, vegetation recovery, the timing of management practices and weather conditions after clear-cutting (Ahtiainen and Huttunen 1999;Mattsson et al 2003;Gundersen et al 2006;Palviainen et al 2007;Kreutzweiser et al 2008;Löfgren et al 2009;Futter et al 2010;Palviainen et al 2014). In addition to above-mentioned factors, the location of clear-cut area in relation to the stream may cause variability in treatment effects among studies (Kreutzweiser et al 2008;Abdelnour et al 2011). Also the properties of buffer zones may affect responses (Gundersen et al 2010).…”

Section: Specific Concentrationsmentioning

confidence: 99%

“…The increases in the concentrations of N fractions in stream water could result from higher deposition loads due to the lack of N retention by tree canopy (Piirainen et al 2002), reduced nutrient uptake by trees and understory vegetation (Palviainen et al 2007), and increased nitrification in litter layer and soil (Paavolainen and Smolander 1998). Nitrate is poorly retained in the soil by sorption and can be easily leached to surface waters (Rosén et al 1996;Kreutzweiser et al 2008). The increases in NO 3 -N concentrations (maximum 190 lg l -1 for the 100 % clear-cut) were considerable smaller than those reported for temperate streams in high N deposition areas, where mean annual NO 3 -N concentrations have been shown to increase by 500-3800 lg l -1 after clear-cutting (Adamson et al 1987;Wiklander et al 1991;Reynolds et al 1995;Feller 2005;Gundersen et al 2006).…”

Section: Specific Concentrationsmentioning

confidence: 99%

“…They increase nutrient concentrations and loads in receiving waters (Ahtiainen and Huttunen 1999;Kreutzweiser et al 2008;Nieminen et al 2010) which may result in degradation of water quality, eutrophication, and formation of harmful algal blooms (Conley et al 2009). In Fennoscandia, several hundred thousand hectares of forests are clearcut annually and the majority of clear-cut areas are prepared mechanically before regeneration operations (Swedish Forest Agency 2013;Ylitalo 2013).…”

Section: Introductionmentioning

confidence: 99%

“…Nitrogen (N) and phosphorus (P) concentrations and loads increase in receiving waters after clear-cutting because the removal of trees decreases water and nutrient uptake and increases runoff (Vitousek et al 1979;Stednick 1996;Kreutzweiser et al 2008). In addition, increased soil temperatures following clear-cutting accelerate mineralization and nitrification in the soil (Paavolainen and Smolander 1998;Smolander et al 2001) and nutrients are released from decomposing logging residues (Palviainen et al 2004).…”

Section: Introductionmentioning

confidence: 99%

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A method to estimate the impact of clear-cutting on nutrient concentrations in boreal headwater streams

Palviainen

Finér

Laurén

et al. 2015

Ambio

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Large-scale forestry operations, like clearcutting, may impair surface water quality if not done with environmental considerations in mind. Catchment and country level estimates of nutrient loads from forestry are generally based on specific export values, i.e., changes in annual exports due to the implemented forestry operations expressed in kg ha -1 . We introduce here a specific concentration approach as a method to estimate the impact of clear-cutting on nutrient concentrations and export in headwater streams. This new method is potentially a more dynamic and flexible tool to estimate nutrient loads caused by forestry, because variation in annual runoff can be taken into account in load assessments. We combined water quality data from eight boreal headwater catchment pairs located in Finland and Sweden, where the effect of clear-cutting on stream water quality has been studied experimentally. Statistically significant specific concentration values could be produced for total nitrogen, nitrate, ammonium, and phosphate. The significant increases in the concentrations of these nutrients occurred between 2 and 6 years after clearcutting. Significant specific concentration values could not be produced for total phosphorus and total organic carbon with the whole dataset, although in some single studies significant increases in their concentrations after clear-cutting were observed. The presented method enables taking into account variation in runoff, temporal dynamics of effects, and the proportional size of the treated area in load calculations. The number of existing studies considering large site-specific variation in responses to clear-cutting is small, and therefore further empirical studies are needed to improve predictive capabilities of the specific concentration values.

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Section: Specific Concentrationssupporting

confidence: 85%

Section: Specific Concentrationsmentioning

confidence: 99%

Section: Specific Concentrationsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A method to estimate the impact of clear-cutting on nutrient concentrations in boreal headwater streams

Palviainen

Finér

Laurén

et al. 2015

Ambio

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Drivers of increased organic carbon concentrations in stream water following forest disturbance: Separating effects of changes in flow pathways and soil warming

et al. 2013

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[1] Forest disturbance such as clear-cutting has been identified as an important factor for increasing dissolved organic carbon (DOC) concentrations in boreal streams. We used a long-term data set of soil temperature, soil moisture, shallow groundwater (GW) levels, and stream DOC concentrations from three boreal first-order streams to investigate mechanisms causing these increases. Clear-cutting was found to alter soil conditions with warmer and wetter soils during summer. The application of a riparian flow concentration integration model (RIM) explained a major part of variation in stream [DOC] arising from changing flow pathways in riparian soils during the pretreatment period (r 2 = 0.4-0.7), but less well after the harvest. Model residuals were sensitive to changes in soil temperature. The linear regression models for the temperature dependence of [DOC] in soils were not different in the disturbed and undisturbed catchments, whereas a nonlinear response to soil moisture was found. Overall these results suggest that the increased DOC mobilization after forest disturbance is caused by (i) increased GW levels leading to increased water fluxes in shallow flow path in riparian soils and (ii) increased soil temperature increasing the DOC availability in soils during summer. These relationships indicate that the mechanisms of DOC mobilization after forest disturbance are not different to those of undisturbed catchments, but that catchment soils respond to the higher hydro-climatic variation observed after clear-cutting. This highlights the sensitivity of boreal streams to changes in the energy and water balance, which may be altered as a result of both land management and climate change.Citation: Schelker, J., T. Grabs, K. Bishop, and H. Laudon (2013), Drivers of increased organic carbon concentrations in stream water following forest disturbance: Separating effects of changes in flow pathways and soil warming, J. Geophys.

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Forest harvest contribution to Boreal freshwater methyl mercury load

Kronberg

Drott

Jiskra

et al. 2016

Global Biogeochemical Cycles

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Effects of Boreal forest harvest on mercury (Hg) and methyl mercury (MeHg) soil pools and export by stream runoff were quantified by comparing 10 reference watersheds (REFs) covered by >80 year old Norway spruce (Picea abies Karst.) forests with 10 similar watersheds subjected to clear-cutting (CCs). While total Hg soil storage did not change, MeHg pools increased seven times (p = 0.006) in the organic topsoil 2 years after clear-cutting. In undulating terrain, situated above the postglacial marine limit (ML) of the ancient Baltic Sea, the mass ratio between flux-weighted MeHg and dissolved organic carbon (MeHg/DOC) in stream runoff increased 1.8 times (p < 0.004) as a consequence of forest harvest. When recalculated to 100% clear-cutting of the watershed, the annual MeHg stream export increased 3.8 times (p = 0.047). Below the ML, where the terrain was flatter, neither the MeHg/DOC ratio nor the annual export of MeHg differed between REFs and CCs, likely because of the larger contribution of MeHg exported from peaty soils and small wetlands. The most robust measure, MeHg/DOC, was used to calculate MeHg loadings to Boreal headwaters. If the forest harvest effect lasts 10 years, clear-cutting increases MeHg runoff by 12-20% in Sweden and 2% in the Boreal zone as a whole. In Sweden, having intensely managed forests, 37% and 56% of MeHg are exported from peatlands and forest soils, respectively, and forest clear-cutting is adding another 6.6%. In the Boreal zone as a whole peatlands and forests soils contribute with 53% and 46%, respectively, and clearcutting is estimated to add another 1.0%. An expected rapid increase in Boreal forest harvest and disturbance urge for inclusion of land use effects in mercury biogeochemical cycling models at different scales.

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Logging impacts on the biogeochemistry of boreal forest soils and nutrient export to aquatic systems: A review

Cited by 278 publications

References 168 publications

A method to estimate the impact of clear-cutting on nutrient concentrations in boreal headwater streams

A method to estimate the impact of clear-cutting on nutrient concentrations in boreal headwater streams

Drivers of increased organic carbon concentrations in stream water following forest disturbance: Separating effects of changes in flow pathways and soil warming

Forest harvest contribution to Boreal freshwater methyl mercury load

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