Abstract
AbstractWood ash amendment to forest soils contributes to the sustainability of the growing bioenergy industry, not only through decreased wood ash waste disposal in landfills but also by increasing soil/site productivity and tree growth. However, tree growth studies to date have reported variable responses to wood ash, highlighting the need to identify proper application rates under various soil/site conditions to maximize their benefits. We explored the influence of tree species, wood ash nutrient application rates, time since application, stand development stage, and initial (i.e., before wood ash application) soil pH and N on short‐term tree growth response to wood ash amendment across eight unique study sites spanning five Canadian Provinces. Jack pine (Pinus banksiana Lamb) had the most positive response to wood ash amendment compared to white (Picea glauca Moench), hybrid (Picea engelmannii x glauca Parry), and black spruce (Picea mariana Miller), where increasing nutrient application rates increased height growth response. In comparison, black spruce had the most negative response to wood ash amendment, where increasing nutrient application rates slightly decreased height growth response. Site as a random effect explained additional variation, highlighting the importance of other unidentified site characteristics. By examining trends in short‐term growth response across multiple studies with variable site characteristics, we found growth response differed by tree species and nutrient application rates, and that jack pine is a promising candidate for wood ash amendment. These results contribute to our knowledge of optimal wood ash amendment practices and environmentally sustainable bioenergy production.
Highlights
Wood ash amendment to forest soils is a common practice in some European countries and is of growing interest in Canada where bioenergy and associated wood ash waste production is on the rise (Hannam et al, 2018)
When wood ash is applied to forest soils, it has the potential to contribute to the sustainability of the growing bioenergy industry, through decreased waste disposal in landfills and by increasing soil/site productivity and tree growth (Augusto, Bakker, & Meredieu, 2008; Reid & Watmough, 2014)
For the significant interaction between tree species and nutrient application rate, jack pine height growth response was positive in relation to increasing nutrient application rate and was significantly greater than the response of white and hybrid spruce spp. (Figure 3)
Summary
Canadian Wood Fibre Centre; Natural Resources Canada; Natural Sciences and Engineering Research Council of Canada, Grant/Award Number: 45041213; Resolute Forest Products; Quebec Ministry of Forests, Wildlife and Parks; ALRF Society; Canfor Pulp; Fraser Basin Council; BC Ministry of Forests, Lands, Natural Resource Operations and Rural Development; AshNet
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