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活性氮向阿巴拉契亚山脉南部落叶林的大气沉降。

Atmospheric deposition of reactive nitrogen to a deciduous forest in the southern Appalachian Mountains.

作者信息

Walker John T, Chen Xi, Wu Zhiyong, Schwede Donna, Daly Ryan, Djurkovic Aleksandra, Oishi A Christopher, Edgerton Eric, Bash Jesse, Knoepp Jennifer, Puchalski Melissa, Iiames John, Miniat Chelcy F

机构信息

U.S. Environmental Protection Agency, Office of Research and Development, Durham, NC, USA.

U.S. Department of Agriculture, Forest Service, Southern Research Station, Coweeta Hydrologic Laboratory, Otto, NC, USA.

出版信息

Biogeosciences. 2023 Mar 9;20(5):971-995. doi: 10.5194/bg-20-971-2023.

DOI:10.5194/bg-20-971-2023
PMID:39434786
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11492993/
Abstract

Assessing nutrient critical load exceedances requires complete and accurate atmospheric deposition budgets for reactive nitrogen (N). The exceedance is the total amount of N deposited to the ecosystem in excess of the critical load, which is the amount of N input below which harmful effects do not occur. Total deposition includes all forms of N (i.e., organic and inorganic) deposited to the ecosystem by wet and dry pathways. Here we present results from the Southern Appalachian Nitrogen Deposition Study (SANDS), in which a combination of measurements and field-scale modeling was used to develop a complete annual N deposition budget for a deciduous forest at the Coweeta Hydrologic Laboratory. Wet deposition of ammonium, nitrate, nitrite, and bulk organic N were measured directly. The dry deposited N fraction was estimated using a bidirectional resistance-based model driven with speciated measurements of N air concentrations (e.g., ammonia, ammonium aerosol, nitric acid, nitrate aerosol, bulk organic N in aerosol, total alkyl nitrates, and total peroxy nitrates), micrometeorology, canopy structure, and biogeochemistry. Total annual deposition was 6.7 kg N ha yr, which is on the upper end of N critical load estimates recently developed for similar ecosystems in the nearby Great Smoky Mountains National Park. Of the total (wet + dry) budget, 51.1% was contributed by reduced forms of N , with oxidized and organic forms contributing ~41.3% and 7.6%, respectively. Our results indicate that reductions in deposition would be needed to achieve the lowest estimates (3.0 kg N ha yr) of N critical loads in southern Appalachian forests.

摘要

评估养分临界负荷超标情况需要有完整且准确的活性氮(N)大气沉降预算。超标量是指沉积到生态系统中的氮总量超过临界负荷的部分,临界负荷是指低于该输入量不会产生有害影响的氮输入量。总沉降包括通过湿沉降和干沉降途径沉积到生态系统中的所有形式的氮(即有机氮和无机氮)。在此,我们展示了来自阿巴拉契亚南部氮沉降研究(SANDS)的结果,该研究采用测量和野外尺度建模相结合的方法,为考伊塔水文实验室的一片落叶林制定了完整的年度氮沉降预算。直接测量了铵、硝酸盐、亚硝酸盐和总有机氮的湿沉降。利用基于双向阻力的模型估算干沉降氮部分,该模型由氮空气浓度(如氨、铵气溶胶、硝酸、硝酸盐气溶胶、气溶胶中的总有机氮、总烷基硝酸盐和总过氧硝酸盐)的特定测量值、微气象学、冠层结构和生物地球化学驱动。年总沉降量约为6.7千克氮/公顷·年,这处于最近为附近大烟山国家公园类似生态系统制定的氮临界负荷估计值的上限。在总(湿沉降 + 干沉降)预算中,还原态氮贡献了51.1%,氧化态氮和有机态氮分别贡献了约41.3%和7.6%。我们的结果表明,需要减少沉降量,才能实现阿巴拉契亚南部森林氮临界负荷的最低估计值(约3.0千克氮/公顷·年)。

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