Factors Affecting Gaseous Mercury (Hg) Emissions from Soils: Insights from Disturbance due to Frest Harvesting and Hg Source Depth Manipulation

Mazur, Maxwell

05 December 2013

This thesis explored the impacts of forest harvesting on gaseous elemental mercury emissions from forest soils in both field and laboratory studies, through novel use of enriched mercury isotope tracers. Forest floor Hg emissions, sourced from legacy deposition, increased proportionally to the vegetation quantity removed, with biomass harvesting most exacerbating emissions. Contemporary Hg deposition did not appear to be influenced by harvesting. Some of the tracer was rapidly lost to the atmosphere (~8%), but most was sequestered within the soil. Two regimes facilitating Hg emissions were observed in low-light conditions. Under extremely dry conditions deeper Hg sources (> 2cm depth) were as equally susceptible to emission as shallower sources. Following wetting to field capacity, emissions were elevated only from shallow sources, likely as a result of upward capillary transport. Impacts of vegetation removal and dry fluxes are previously uncharacterized and may constitute large additional sources to regional atmospheric Hg cycling.

Mercury

Emission

Forest Harvesting

Soil

Isotope

Source Depth

Dry Flux

Soil Wetting

Flux

Wet Flux

Solar Radiation

Soil Moisture

Leaf Litter

Sequestration

ICP-MS

Tekran

Tracer

Enriched Mercury Isotope

Forest Floor

Deposition

Biomass Harvesting

Capillary Transport

Hg

Cycling

0368

Factors Affecting Gaseous Mercury (Hg) Emissions from Soils: Insights from Disturbance due to Frest Harvesting and Hg Source Depth Manipulation

Mazur, Maxwell

05 December 2013

This thesis explored the impacts of forest harvesting on gaseous elemental mercury emissions from forest soils in both field and laboratory studies, through novel use of enriched mercury isotope tracers. Forest floor Hg emissions, sourced from legacy deposition, increased proportionally to the vegetation quantity removed, with biomass harvesting most exacerbating emissions. Contemporary Hg deposition did not appear to be influenced by harvesting. Some of the tracer was rapidly lost to the atmosphere (~8%), but most was sequestered within the soil. Two regimes facilitating Hg emissions were observed in low-light conditions. Under extremely dry conditions deeper Hg sources (> 2cm depth) were as equally susceptible to emission as shallower sources. Following wetting to field capacity, emissions were elevated only from shallow sources, likely as a result of upward capillary transport. Impacts of vegetation removal and dry fluxes are previously uncharacterized and may constitute large additional sources to regional atmospheric Hg cycling.

Mercury

Emission

Forest Harvesting

Soil

Isotope

Source Depth

Dry Flux

Soil Wetting

Flux

Wet Flux

Solar Radiation

Soil Moisture

Leaf Litter

Sequestration

ICP-MS

Tekran

Tracer

Enriched Mercury Isotope

Forest Floor

Deposition

Biomass Harvesting

Capillary Transport

Hg

Cycling

0368