Department of Biology, Villanova University, Villanova, PA 19085, USA; Faculty of Science and Technology, Athabasca University, Athabasca, Alberta T9S 3A3, Canada; Center for Biodiversity and Ecosystem Stewardship, Villanova University, Villanova, PA 19085, USA.
Department of Plant Biology, Southern Illinois University, Carbondale, IL 62901, USA.
Sci Total Environ. 2020 Sep 1;733:138619. doi: 10.1016/j.scitotenv.2020.138619. Epub 2020 May 5.
Bogs and fens cover 6 and 21%, respectively, of the 140,329 km Oil Sands Administrative Area in northern Alberta. Regional background atmospheric N deposition is low (<2 kg N ha yr), but oil sands development has led to increasing N deposition (as high as 17 kg N ha yr). To examine responses to N deposition, over five years, we experimentally applied N (as NHNO) to a poor fen near Mariana Lake, Alberta, unaffected by oil sands activities, at rates of 0, 5, 10, 15, 20, and 25 kg N ha yr, plus controls (no water or N addition). At Mariana Lake Poor Fen (MLPF), increasing N addition: 1) progressively inhibited N-fixation; 2) had no effect on net primary production (NPP) of Sphagnum fuscum or S. angustifolium, while stimulating S. magellanicum NPP; 3) led to decreased abundance of S. fuscum and increased abundance of S. angustifolium, S. magellanicum, Andromeda polifolia, Vaccinium oxycoccos, and of vascular plants in general; 4) led to an increase in stem N concentrations in S. angustifolium and S. magellanicum, and an increase in leaf N concentrations in Chamaedaphne calyculata, Andromeda polifolia, and Vaccinium oxycoccos; 5) stimulated root biomass and production; 6) stimulated decomposition of cellulose, but not of Sphagnum or vascular plant litter; and 7) had no or minimal effects on net N mineralization in surface peat, NH-N, NO-N or DON concentrations in surface porewater, or peat microbial composition. Increasing N addition led to a switch from new N inputs being taken up primarily by Sphagnum to being taken up primarily by shrubs. MLPF responses to increasing N addition did not exhibit threshold triggers, but rather began as soon as N additions increased. Considering all responses to N addition, we recommend a critical load for poor fens in Alberta of 3 kg N ha yr.
博格斯和芬恩分别覆盖了艾伯塔省北部 140329 平方公里油砂管理区的 6%和 21%。区域背景大气氮沉降量较低(<2kgNha yr),但油砂开发导致氮沉降量增加(高达 17kgNha yr)。为了研究氮沉降的响应,我们在五年多的时间里,在艾伯塔省马里亚纳湖附近的一个贫沼泽地(不受油砂活动影响)进行了实验,用 NHNO 以 0、5、10、15、20 和 25kgNha yr 的速率添加氮,以及对照(不加水或不添加氮)。在马里亚纳湖贫沼泽地(MLPF),随着氮添加量的增加:1)逐渐抑制了固氮作用;2)对 Sphagnum fuscum 或 S. angustifolium 的净初级生产力(NPP)没有影响,而刺激了 S. magellanicum 的 NPP;3)导致 S. fuscum 的丰度减少,S. angustifolium、S. magellanicum、Andromeda polifolia、Vaccinium oxycoccos 和一般维管束植物的丰度增加;4)导致 S. angustifolium 和 S. magellanicum 的茎 N 浓度增加,Chamaedaphne calyculata、Andromeda polifolia 和 Vaccinium oxycoccos 的叶 N 浓度增加;5)刺激了根系生物量和生产力;6)刺激了纤维素的分解,但不刺激 Sphagnum 或维管束植物凋落物的分解;7)对表层泥炭中的净氮矿化、表层孔隙水中的 NH-N、NO-N 或 DON 浓度或泥炭微生物组成没有影响或影响很小。随着氮添加量的增加,新氮的输入主要由 Sphagnum 吸收转变为主要由灌木吸收。MLPF 对氮添加的响应没有表现出阈值触发,而是随着氮添加量的增加而开始。考虑到对氮添加的所有响应,我们建议艾伯塔省贫沼泽地的氮临界负荷为 3kgNha yr。
