Correction to: Background nitrogen deposition controls the effects of experimental nitrogen addition on soil gross N transformations in forest ecosystems

Atmospheric nitrogen and sulfur deposition is an important effect of atmospheric pollution and may affect forest ecosystems positively, for example enhancing tree growth, or negatively, for example causing acidification, eutrophication, cation depletion in soil or nutritional imbalances in trees. To assess and design measures to reduce the negative impacts of deposition, a good estimate of the deposition amount is needed, either by direct measurement or by modeling. In order to evaluate the precision of both approaches and to identify possible improvements, we compared the deposition estimates obtained using an Eulerian model with the measurements performed by two large independent networks covering most of Europe. The results are in good agreement (bias <25%) for sulfate and nitrate open field deposition, while larger differences are more evident for ammonium deposition, likely due to the greater influence of local ammonia sources. Modeled sulfur total deposition compares well with throughfall deposition measured in forest plots, while the estimate of nitrogen deposition is affected by the tree canopy. The geographical distribution of pollutant deposition and of outlier sites where model and measurements show larger differences are discussed.

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Fungal grass endophytes, grass cultivars, nitrogen deposition and the association with colonising insects

NZGA: Research and Practice Series ◽

10.33584/rps.13.2006.3085 ◽

2007 ◽

Vol 13 ◽

pp. 53-57

Author(s):

J. Krauss ◽

S.A. HÃ¤rri ◽

L. Bush ◽

S.A. Power ◽

C.B. MÃ¼ller

Keyword(s):

Field Experiment ◽

Nitrogen Deposition ◽

Fungal Endophytes ◽

Nitrogen Addition ◽

Aphid Species ◽

Specific Response ◽

Cereal Aphid ◽

Pasture Grasses ◽

Aphid Parasitoids ◽

Endophyte Infection

Fungal endophytes associated with pasture grasses can have community-wide effects on insect consumers. Here we asked the question to what degree endophyte infection, simulated nitrogen deposition and grass cultivar influence the abundance of colonising herbivores and their natural enemies. In a fully randomised field experiment, consisting of four Lolium perenne monocultures of known endophyte infection status and a nitrogen addition treatment, we determined the abundance of colonising aphids, their parasitoids and predators, and other grass herbivores. The three colonising cereal aphid species did not respond to endophyte infection, possibly because peramine concentrations were relatively low (3.9 ÃŽÂ¼g/g). There was a significant interaction between nitrogen addition and plant cultivar on the abundance of Sitobion avenae, suggesting a cultivar-specific response to nitrogen addition. Aphid predators were affected by an interaction between endophyte and plant cultivar, but abundance of aphid parasitoids and other grass herbivores was not affected by any treatment. The fungus Claviceps purpurea naturally infected our experimental plants and infection rates differed among cultivars and were more likely to occur on endophyte-infected plants, in particular on wild-type Samson. We conclude that strong effects of endophytes on insect abundance may not occur in systems built upon L. perenne because overall peramine levels rarely reach threshold levels for insect toxicity. Keywords: fungal endosymbionts, multitrophic interactions, field experiment, insect food webs, alkaloids

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Response of litter decomposition and the soil environment to one-year nitrogen addition in a Schrenk spruce forest in the Tianshan Mountains, China

Scientific Reports ◽

10.1038/s41598-021-04623-8 ◽

2022 ◽

Vol 12 (1) ◽

Author(s):

Zhaolong Ding ◽

Xu Liu ◽

Lu Gong ◽

Xin Chen ◽

Jingjing Zhao ◽

...

Keyword(s):

Nitrogen Deposition ◽

Litter Decomposition ◽

Forest Ecosystems ◽

N Deposition ◽

Tianshan Mountains ◽

Control Treatment ◽

N Addition ◽

Soil Environment ◽

N Application ◽

Positive Effect

AbstractHuman activities have increased the input of nitrogen (N) to forest ecosystems and have greatly affected litter decomposition and the soil environment. But differences in forests with different nitrogen deposition backgrounds. To better understand the response of litter decomposition and soil environment of N-limited forest to nitrogen deposition. We established an in situ experiment to simulate the effects of N deposition on soil and litter ecosystem processes in a Picea schrenkiana forest in the Tianshan Mountains, China. This study included four N treatments: control (no N addition), low N addition (LN: 5 kg N ha−1 a−1), medium N addition (MN: 10 kg N ha−1 a−1) and high N addition (HN: 20 kg N ha−1 a−1). Our results showed that N addition had a significant effect on litter decomposition and the soil environment. Litter mass loss in the LN treatment and in the MN treatment was significantly higher than that in the control treatment. In contrast, the amount of litter lost in the HN treatment was significantly lower than the other treatments. N application inhibited the degradation of lignin but promoted the breakdown of cellulose. The carbon (C), N, and phosphorus (P) contents of litter did not differ significantly among the treatments, but LN promoted the release of C and P. Our results also showed that soil pH decreased with increasing nitrogen application rates, while soil enzyme activity showed the opposite trend. In addition, the results of redundancy analysis (RDA) and correlation analyses showed that the soil environment was closely related to litter decomposition. Soil enzymes had a positive effect on litter decomposition rates, and N addition amplified these correlations. Our study confirmed that N application had effects on litter decomposition and the soil environment in a N-limited P. schrenkiana forest. LN had a strong positive effect on litter decomposition and the soil environment, while HN was significantly negative. Therefore, increased N deposition may have a negative effect on material cycling of similar forest ecosystems in the near future.

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Comparative analysis of the influence of climate change and nitrogen deposition on carbon sequestration in forest ecosystems in European Russia: simulation modelling approach

Biogeosciences ◽

10.5194/bg-9-4757-2012 ◽

2012 ◽

Vol 9 (11) ◽

pp. 4757-4770 ◽

Cited By ~ 9

Author(s):

A. S. Komarov ◽

V. N. Shanin

Keyword(s):

Climate Change ◽

Organic Matter ◽

Nitrogen Deposition ◽

Forest Ecosystems ◽

General Scheme ◽

Organic Matter Content ◽

Matter Content ◽

Forest Growth ◽

Deciduous Tree ◽

Change Scenario

Abstract. An individual-based simulation model, EFIMOD, was used to simulate the response of forest ecosystems to climate change and additional nitrogen deposition. The general scheme of the model includes forest growth depending on nitrogen uptake by plants and mineralization of soil organic matter. The mineralization rate is dependent on nitrogen content in litter and forest floor horizons. Three large forest areas in European Central Russia with a total area of about 17 000 km2 in distinct environmental conditions were chosen. Simulations were carried out with two climatic scenarios (ambient climate and climate change) and different levels of nitrogen deposition (ambient value and increase by 6 and 12 kg N ha−1 yr−1). The simulations showed that increased nitrogen deposition leads to increased productivity of trees, increased organic matter content in organic soil horizons, and an increased portion of deciduous tree species. For the climate change scenario, the same effects on forest productivity and similar shifts in species composition were predicted but the accumulation of organic matter in soil was decreased.

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