Geology Department, School of Natural Sciences, Trinity College Dublin, Dublin 2, Ireland.
Water Res. 2012 Aug;46(12):3723-36. doi: 10.1016/j.watres.2012.03.004. Epub 2012 Mar 14.
(15)N and (18)O isotope abundance analyses in nitrate (NO(3)(-)) (expressed as δ(15)N-NO(3)(-) and δ(18)O-NO(3)(-) values respectively) have often been used in research to help identify NO(3)(-) sources in rural groundwater. However, questions have been raised over the limitations as overlaps in δ values may occur between N source types early in the leaching process. The aim of this study was to evaluate the utility of using stable isotopes for nitrate source tracking through the determination of δ(15)N-NO(3)(-) and δ(18)O-NO(3)(-) in the unsaturated zone from varying N source types (artificial fertiliser, dairy wastewater and cow slurry) and rates with contrasting isotopic compositions. Despite NO(3)(-) concentrations being often elevated, soil-water nitrate poorly mirrored the (15)N content of applied N and therefore, δ(15)N-NO(3)(-) values were of limited assistance in clearly associating nitrate leaching with N inputs. Results suggest that the mineralisation and the nitrification of soil organic N, stimulated by previous and current intensive management, masked the cause of leaching from the isotopic prospective. δ(18)O-NO(3)(-) was of little use, as most values were close to or within the range expected for nitrification regardless of the treatment, which was attributed to the remineralisation of nitrate assimilated by bacteria (mineralisation-immobilisation turnover or MIT) or plants. Only in limited circumstances (low fertiliser application rate in tillage) could direct leaching of synthetic nitrate fertiliser be identified (δ(15)N-NO(3)(-)<0‰ and δ(18)O-NO(3)(-)>15‰). Nevertheless, some useful differences emerged between treatments. δ(15)N-NO(3)(-) values were lower where artificial fertiliser was applied compared with the unfertilised controls and organic waste treatments. Importantly, δ(15)N-NO(3)(-) and δ(18)O-NO(3)(-) variables were negatively correlated in the artificial fertiliser treatment (0.001≤p≤0.05, attributed to the varying proportion of fertiliser-derived and synthetic nitrate being leached) while positively correlated in the dairy wastewater plots (p≤0.01, attributed to limited denitrification). These results suggest that it may be possible to distinguish some nitrate sources if analysing correlations between δ variables from the unsaturated zone. In grassland, the above correlations were related to N input rates, which partly controlled nitrate concentrations in the artificial fertiliser plots (high inputs translated into higher NO(3)(-) concentrations with an increasing proportion of fertiliser-derived and synthetic nitrate) and denitrification in the dairy wastewater plots (high inputs corresponded to more denitrification). As a consequence, nitrate source identification in grassland was more efficient at higher input rates due to differences in δ values widening between treatments.
(15)N 和 (18)O 同位素丰度分析在硝酸盐 (NO(3)(-)) 中经常被用于研究,以帮助识别农村地下水的硝酸盐来源。然而,人们对其局限性提出了质疑,因为在淋滤过程的早期,氮源类型之间可能会出现 δ 值的重叠。本研究的目的是评估利用稳定同位素追踪硝酸盐来源的效用,通过测定不同氮源类型(人工肥料、奶牛废水和牛粪)和不同速率下非饱和带中 δ(15)N-NO(3)(-) 和 δ(18)O-NO(3)(-)。尽管硝酸盐浓度经常升高,但土壤-水中的硝酸盐很少反映出应用氮的 (15)N 含量,因此,δ(15)N-NO(3)(-) 值在明确将硝酸盐淋滤与氮输入联系起来方面帮助有限。结果表明,由于先前和当前集约化管理刺激的土壤有机氮的矿化和硝化作用,掩盖了从同位素角度来看淋滤的原因。δ(18)O-NO(3)(-) 几乎没有用处,因为大多数值接近或在硝化作用的预期范围内,无论处理方式如何,这归因于细菌同化的硝酸盐的再矿化(矿化-固定化周转或 MIT)或植物。只有在有限的情况下(耕作中低施肥率)才能确定合成硝酸盐肥料的直接淋滤(δ(15)N-NO(3)(-)<0‰和 δ(18)O-NO(3)(-)>15‰)。然而,处理之间出现了一些有用的差异。与未施肥对照和有机废物处理相比,人工施肥时的 δ(15)N-NO(3)(-) 值较低。重要的是,人工施肥处理中 δ(15)N-NO(3)(-) 和 δ(18)O-NO(3)(-) 变量呈负相关(0.001≤p≤0.05,归因于施肥衍生和合成硝酸盐的淋滤比例不同),而在奶牛废水处理中呈正相关(p≤0.01,归因于有限的反硝化作用)。这些结果表明,如果分析非饱和带中 δ 变量之间的相关性,可能有可能区分一些硝酸盐来源。在草原上,上述相关性与氮输入速率有关,氮输入速率部分控制了人工施肥处理中硝酸盐的浓度(高输入导致更多的硝酸盐浓度,同时施肥衍生和合成硝酸盐的比例增加)和奶牛废水处理中硝酸盐的反硝化作用(高输入对应更多的反硝化作用)。因此,由于处理之间的 δ 值差异扩大,在高输入速率下,硝酸盐源的识别效率更高。
