Département des Sciences Naturelles, Institut des Sciences de la Forêt Tempérée (ISFORT), Université du Québec en Outaouais, 58 rue Principale, Ripon, QC J0V 1V0, Canada.
Department of Natural Resource Sciences, Macdonald Campus of McGill University, 21111 Lakeshore Road, Ste-Anne-de-Bellevue, QC H9X 3V9, Canada.
Sci Total Environ. 2019 May 1;663:537-547. doi: 10.1016/j.scitotenv.2019.01.337. Epub 2019 Jan 26.
Alkaline residuals, such as wood ash and lime mud generated from pulp and paper mills, could be recycled as liming agents in sugar maple (Acer saccharum Marsh.) forests affected by soil acidification. The objectives of this study were (1) to evaluate soil chemistry, in particular soil acidity, after the application of three alkaline residuals from the pulp and paper industry, and (2) to determine if these alkaline residuals altered soil greenhouse gas (GHG) emissions as a result of the change in soil pH or due to their chemical composition. Soil properties and GHG fluxes were monitored for two years after alkaline residuals were applied to six forest sites dominated by sugar maple in southeastern Quebec, Canada. Each site received six treatments: wood ash applied at 5, 10 and 20 t ha, lime mud (7.5 t ha), a mixture of slaker grits and green liquor sludge (7 t ha) and an unamended control. These treatments had acid-neutralizing power from 0 to 9 t ha. All alkaline residuals buffered soil acidity as a function of their neutralizing power, and more neutralization occurred in the forest floor layer than in the underlying mineral soil. In the forest floor, the alkaline residual treatments significantly increased pH by more than one unit, nearly doubled the base saturation, and reduced exchangeable acidity, Al and Fe concentrations compared to control plots. The CO and NO fluxes were lower after application of alkaline residuals, and this was related to the soil pH increase and the type of alkaline residual applied. Lime mud was more effective at reducing GHG fluxes than other alkaline residuals. We conclude that these alkaline residuals can effectively counteract soil acidity in sugar maple forests without increasing soil GHG emissions, at least in the short term.
碱性残留物,如木灰和石灰泥,可从纸浆和造纸厂中回收,作为受土壤酸化影响的糖枫(Acer saccharum Marsh.)森林的石灰剂加以再利用。本研究的目的是:(1)评估三种纸浆和造纸工业碱性残留物施用后土壤化学特性,特别是土壤酸度;(2)确定这些碱性残留物是否通过改变土壤 pH 值或由于其化学成分而改变土壤温室气体(GHG)排放。在加拿大魁北克东南部以糖枫为主的六个森林地点,施用碱性残留物两年后监测土壤特性和 GHG 通量。每个地点接受六种处理:木灰以 5、10 和 20 t ha 施用、石灰泥(7.5 t ha)、熟石灰渣和绿液污泥的混合物(7 t ha)和未施肥对照。这些处理的中和能力为 0 至 9 t ha。所有碱性残留物均通过中和能力缓冲土壤酸度,在林冠层中的中和能力比在下层矿物土壤中更高。在林冠层中,碱性残留物处理使 pH 值显著增加一个单位以上,将基础饱和度提高近一倍,并降低与对照相比,可交换酸度、Al 和 Fe 浓度。施用碱性残留物后,CO 和 NO 通量降低,这与土壤 pH 值升高和施用的碱性残留物类型有关。石灰泥比其他碱性残留物更有效地降低 GHG 通量。我们的结论是,这些碱性残留物可以有效地中和糖枫林中的土壤酸度,而不会增加土壤 GHG 排放,至少在短期内如此。
