Your search keyword '"Schoenau, J."' showing total 4 results

1. First Rotation Biomass Production and Nutrient Cycling within Short-Rotation Coppice Willow Plantations in Saskatchewan, Canada.

Author

Hangs, R., Schoenau, J., Rees, K., Bélanger, N., Volk, T., and Jensen, T.

Subjects

*NUTRIENT cycles, *CROP rotation, *LEACHING, *DENITRIFICATION, *CHEMICAL reduction, *WILLOWS

Abstract

Although numerous studies have quantified different social, economic, energetic, and environmental benefits associated with short-rotation coppice (SRC) willow plantations, comprehensive assessments of nutrient cycling are rare. The objective of this study was to examine the biomass production and attendant biogeochemical cycling of nitrogen (N), phosphorus (P), potassium (K), sulfur (S), calcium (Ca), and magnesium (Mg) during the initial 4-year rotation of six willow varieties grown at four locations along a 500 km north-south pedoclimatic gradient within Saskatchewan, Canada. Nutrient budgets consisted of quantifying various nutrient inputs (e.g., atmospheric deposition and soil mineral weathering), outputs (e.g., fine and coarse root biomass, leaf biomass, harvested biomass, leaching, and denitrification), and transfers (e.g., soil organic matter mineralization, canopy exchange, leaf litter decomposition, and fine root turnover) associated with the plant available soil nutrient pool. Total above- and below-ground production during the rotation was approximately 40 Mg ha, with calculated soil nutrient budget deficits (i.e., nutrient outputs > inputs + transfers) of 17, 39, 112, 271, and 74 kg ha for N, P, K, Ca, and Mg, respectively, averaged across the varieties and sites, but a soil S surplus of 60 kg ha. While soil nutrient budget deficits varied among sites, there were no significant differences ( P > 0.05) among willow varieties. Despite the relatively low nutrient-demanding nature of willow and negligible leaching or denitrification losses, nutrient export in harvested biomass over multiple rotations will require soil nutrient amendments to maintain SRC willow productivity, particularly N and P, albeit a fraction of the amount required for annual agronomic crops. [ABSTRACT FROM AUTHOR]

Published

2014

2. Leaf Litter Decomposition and Nutrient-Release Characteristics of Several Willow Varieties Within Short-Rotation Coppice Plantations in Saskatchewan, Canada.

Author

Hangs, R., Schoenau, J., Rees, K., Bélanger, N., and Volk, T.

Subjects

*FOREST litter, *WILLOWS, *NUTRIENT cycles, *FOREST litter decomposition, *BIODEGRADATION of humus, *BIOMASS

Abstract

Quantifying short-rotation coppice (SRC) willow leaf litter dynamics will improve our understanding of carbon (C) sequestration and nutrient cycling potentials within these biomass energy plantations and provide valuable data for model validation. The objective of this study was to quantify the decomposition rate constants ( k) and decomposition limit values (LV), along with associated release rates ( k) and release limits (LV) of nitrogen (N), phosphorus (P), potassium (K), sulphur (S), calcium (Ca), and magnesium (Mg) of leaf litter from several native and exotic willow varieties during an initial 4-year rotation at four sites within Saskatchewan, Canada. The k, LV, k, and LV values varied among the willow varieties, sites, and nutrients, with average values of 1.7 year, 79 %, 0.9 year, and 83 %, respectively. Tissue N had the smallest k and LV values, whereas tissue K and Mg had the largest k and LV values, respectively. The leaf litter production varied among willow varieties and sites with an average biomass accumulation of 7.4 Mg ha after the 4-year rotation and associated C sequestration rate of 0.2 Mg C ha year. The average contribution of nutrients released from leaf litter decomposition during the 4-year rotation to the plant available soil nutrient pool across varieties and sites was 22, 4, 47, 10, 112, and 18 kg ha of N, P, K, S, Ca, and Mg, respectively. Principal component analysis identified numerous key relationships between the measured soil, plant tissue, climate, and microclimate variables and observed willow leaf litter decomposition and nutrient-release characteristics. Our findings support the contention that SRC willow leaf litter is capable of enhancing both soil organic C levels and supplementing soil nutrient availability over time. [ABSTRACT FROM AUTHOR]

Published

2014

3. Measuring Harvestable Biomass in Short-Rotation Willow Bioenergy Plantations Using Light Attenuation.

Author

Hangs, R., Stevenson, F., Schoenau, J., and Rees, K.

Subjects

BIOMASS energy industries, ENERGY harvesting, ENERGY crops, SHORT rotation forestry, PLANTATIONS, ATTENUATION of light, WILLOWS, ALLOMETRY

Abstract

Routine monitoring of above ground biomass within purpose-grown willow biomass energy production systems is important for timing harvest and other operations to maximize profit and increase plantation productivity. The objective of this study was to assess the efficacy of an elegant nondestructive mensurative technique for providing reliable estimates of harvestable biomass for six willow varieties during a 3-year rotation. The LAI-2000 Plant Canopy Analyser was used to measure the stem area index of growing willow and relate it to harvestable biomass at four locations within Saskatchewan, Canada over a 3-year period. Given the highly significant relationship ( R = 0.95; P < 0.0001) between measured stem area index and harvestable willow biomass, independent of variety, age, or location, this simple mensurative technique is a promising alternative for estimating above ground biomass in short-rotation willow plantations. [ABSTRACT FROM AUTHOR]

Published

2013

4. Examining the salt tolerance of willow ( Salix spp.) bioenergy species for use on salt-affected agricultural lands.

Author

Hangs, R. D., Schoenau, J. J., Rees, K. C. J. Van, and Steppuhn, H.

Subjects

WILLOWS, SOIL salinity, BIOMASS energy, ELECTRIC conductivity, FARMS

Published

2011