Potential Environmental Impacts of Bioenergy Harvesting on Soils

Potential Environmental Impacts of Bioenergy Harvesting on Soils

Aspect
Potential Issues
Contributing activities
Examples of mitigating practices
Physical properties:

Moisture

Temperature

Structure

Erosion

Removal of slash and litter layer and disturbance of forest floor leads to exposure of soil surface and drying of surface layers and soil temperature extremes

Changes in soil microclimate

Compaction leads to decreased soil aeration and soil porosity and decreased water infiltration and waterlogged ruts

Clearcutting leads to a loss of evapotranspiration and increased water content and rise of water table and saturation of soil

Exposure of soil surface layers by wind and water leads to erosion

Downed woody debris (DWD) and litterfall removal

Removal of protective roadbed for feedstock

Time of year and soil conditions during operations

Clearcutting and whole-tree harvesting (WTH)

Multiple-pass harvesting

Increased road networks

Heavy mechanized equipment
Maintain protective slash and litter layer on forest floor

Restrict interventions to seasons when soil moisture is low

Use specialized equipment such as high flotation tires and boom-forwarding

Utilize best management practices for road building, as prescribed by the USDA

Orient skid trails and site preparations along slope contours

Minimize interventions by practicing one-pass harvesting

Ameliorate soil compaction through ripping and cultivation

Chemical properties

Nutrients

Toxic substances

pH

Redox potential
Maintaining total capital and availability of nutrients

Increased leaching from the forest floor and mineral soil

Accumulation of toxic substances

Decrease in pH

Anaerobic conditions mobilizing toxic forms of some elements/compounds; altered chemical transformations

Removal of forest biomass throughout the rotation (e.g., WTH, removal of dead wood)

Rotation length and species chosen

Improper use of herbicides, pesticides, fertilizers and wood ash

Oil and hydraulic fluid spills from harvesting machinery

Develop site-specific nutrient management regimes

Avoid windrowing/root raking that results in soil organic matter depletion

Retain nutrient-rich crown biomass on site (e.g., needles, bark, branches, tops)

Harvest deciduous trees in winter, after leaves have fallen

Apply recycled wood ash or fertilizers where needed according to guidelines
Biological properties:

Soil biota is decreased through:

Loss of soil organic matter
Compaction
Drying
Waterlogging
Accumulation of toxic elements
Temperature extremes

See related activities described above

See mitigation strategies above

When using pesticides and fertilizers, follow guidelines established by the USDA

Aspect	Potential Issues	Contributing activities	Examples of mitigating practices
Physical properties: Moisture Temperature Structure Erosion	Removal of slash and litter layer and disturbance of forest floor leads to exposure of soil surface and drying of surface layers and soil temperature extremes Changes in soil microclimate Compaction leads to decreased soil aeration and soil porosity and decreased water infiltration and waterlogged ruts Clearcutting leads to a loss of evapotranspiration and increased water content and rise of water table and saturation of soil Exposure of soil surface layers by wind and water leads to erosion	Downed woody debris (DWD) and litterfall removal Removal of protective roadbed for feedstock Time of year and soil conditions during operations Clearcutting and whole-tree harvesting (WTH) Multiple-pass harvesting Increased road networks Heavy mechanized equipment	Maintain protective slash and litter layer on forest floor Restrict interventions to seasons when soil moisture is low Use specialized equipment such as high flotation tires and boom-forwarding Utilize best management practices for road building, as prescribed by the USDA Orient skid trails and site preparations along slope contours Minimize interventions by practicing one-pass harvesting Ameliorate soil compaction through ripping and cultivation
Chemical properties Nutrients Toxic substances pH Redox potential	Maintaining total capital and availability of nutrients Increased leaching from the forest floor and mineral soil Accumulation of toxic substances Decrease in pH Anaerobic conditions mobilizing toxic forms of some elements/compounds; altered chemical transformations	Removal of forest biomass throughout the rotation (e.g., WTH, removal of dead wood) Rotation length and species chosen Improper use of herbicides, pesticides, fertilizers and wood ash Oil and hydraulic fluid spills from harvesting machinery	Develop site-specific nutrient management regimes Avoid windrowing/root raking that results in soil organic matter depletion Retain nutrient-rich crown biomass on site (e.g., needles, bark, branches, tops) Harvest deciduous trees in winter, after leaves have fallen Apply recycled wood ash or fertilizers where needed according to guidelines
Biological properties:	Soil biota is decreased through: Loss of soil organic matter Compaction Drying Waterlogging Accumulation of toxic elements Temperature extremes	See related activities described above	See mitigation strategies above When using pesticides and fertilizers, follow guidelines established by the USDA

Permission of Use: Used with permission of Brenna Lattimore and C. T. Smith 1/22/08

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