School of Agriculture and Food Science, University College Dublin, Dublin, Ireland.
WSL, Swiss Federal Institute for Forest, Snow and Landscape Research, Birmensdorf, Switzerland.
Glob Chang Biol. 2018 Aug;24(8):3603-3619. doi: 10.1111/gcb.14156. Epub 2018 May 3.
Acid deposition arising from sulphur (S) and nitrogen (N) emissions from fossil fuel combustion and agriculture has contributed to the acidification of terrestrial ecosystems in many regions globally. However, in Europe and North America, S deposition has greatly decreased in recent decades due to emissions controls. In this study, we assessed the response of soil solution chemistry in mineral horizons of European forests to these changes. Trends in pH, acid neutralizing capacity (ANC), major ions, total aluminium (Al ) and dissolved organic carbon were determined for the period 1995-2012. Plots with at least 10 years of observations from the ICP Forests monitoring network were used. Trends were assessed for the upper mineral soil (10-20 cm, 104 plots) and subsoil (40-80 cm, 162 plots). There was a large decrease in the concentration of sulphate (SO42-) in soil solution; over a 10-year period (2000-2010), SO42- decreased by 52% at 10-20 cm and 40% at 40-80 cm. Nitrate was unchanged at 10-20 cm but decreased at 40-80 cm. The decrease in acid anions was accompanied by a large and significant decrease in the concentration of the nutrient base cations: calcium, magnesium and potassium (Bc = Ca + Mg + K ) and Al over the entire dataset. The response of soil solution acidity was nonuniform. At 10-20 cm, ANC increased in acid-sensitive soils (base saturation ≤10%) indicating a recovery, but ANC decreased in soils with base saturation >10%. At 40-80 cm, ANC remained unchanged in acid-sensitive soils (base saturation ≤20%, pHCaCl2 ≤ 4.5) and decreased in better-buffered soils (base saturation >20%, pHCaCl2 > 4.5). In addition, the molar ratio of Bc to Al either did not change or decreased. The results suggest a long-time lag between emission abatement and changes in soil solution acidity and underline the importance of long-term monitoring in evaluating ecosystem response to decreases in deposition.
由于化石燃料燃烧和农业排放的硫(S)和氮(N),全球许多地区的陆地生态系统已经酸化。然而,在欧洲和北美,由于排放控制,S 的沉积在最近几十年大大减少。在这项研究中,我们评估了欧洲森林矿物质土壤溶液化学对这些变化的响应。在 1995-2012 年期间,测定了 pH 值、酸中和能力(ANC)、主要离子、总铝(Al)和溶解有机碳的趋势。使用了 ICP 森林监测网络至少有 10 年观测结果的地块。对上层矿物土壤(10-20cm,104 个地块)和下层土壤(40-80cm,162 个地块)进行了趋势评估。土壤溶液中硫酸盐(SO42-)的浓度有很大的降低;在 10 年期间(2000-2010 年),SO42-在 10-20cm 处减少了 52%,在 40-80cm 处减少了 40%。NO3-在 10-20cm 处没有变化,但在 40-80cm 处减少了。酸阴离子的减少伴随着营养基础阳离子(Bc=Ca+Mg+K)和 Al 浓度的大幅显著降低,整个数据集都有。土壤溶液酸度的响应并不均匀。在 10-20cm 处,ANC 在酸性敏感土壤(基础饱和度≤10%)中增加,表明恢复,但在基础饱和度>10%的土壤中 ANC 减少。在 40-80cm 处,ANC 在酸性敏感土壤(基础饱和度≤20%,pHCaCl2≤4.5)中保持不变,在缓冲能力更好的土壤(基础饱和度>20%,pHCaCl2>4.5)中降低。此外,Bc 与 Al 的摩尔比要么没有变化,要么减少。结果表明,在土壤溶液酸度变化与排放减少之间存在长时间滞后,强调了在评估生态系统对沉积减少的反应时进行长期监测的重要性。
