ABSORPTION OF ATMOSPHERIC NITROGEN BY TUBEROUS

Aim. To study the specifi cities of complex inoculation of spring wheat roots with the bacteria of Azospirillum genus and Chaetomium cochliodes Palliser 3250, and the isolation of bacteria of Azospirillum genus, capable of fi xing atmospheric nitrogen, from the rhizospheric soil, washed-off roots and histoshere. Materials and meth- ods. The phenotypic features of the selected bacteria were identifi ed according to Bergi key. The molecular the polymerase chain reaction and genetic analysis was used for the identifi cation the bacteria. Results. It has been demonstrated that during the introduction into the root system of spring wheat the strain of A. brasilensе 102 actively colonizes rhizospheric soil, root surface and is capable of penetrating into the inner plant tissues. Conclusions. The soil ascomucete of C. cochliodes 3250 promotes better settling down of Azospirillum cells in spring wheat root zone, especially in plant histosphere which induces the increase in the content of chlorophyll a and b in the leaves and yield of the crop.

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Faculty Opinions recommendation of Increasing N abundance in the northwestern Pacific Ocean due to atmospheric nitrogen deposition.

Faculty Opinions – Post-Publication Peer Review of the Biomedical Literature ◽

10.3410/f.13340014.14707136 ◽

2011 ◽

Author(s):

James Elser

Keyword(s):

Pacific Ocean ◽

Nitrogen Deposition ◽

Northwestern Pacific ◽

Atmospheric Nitrogen Deposition ◽

Atmospheric Nitrogen ◽

Northwestern Pacific Ocean

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Atmospheric nitrogen deposition and its environmental implications at a headwater catchment of Taihu Lake Basin, China

Atmospheric Research ◽

10.1016/j.atmosres.2021.105566 ◽

2021 ◽

Vol 256 ◽

pp. 105566

Author(s):

Jianwei Geng ◽

Hengpeng Li ◽

Dongqiang Chen ◽

Xiaofei Nei ◽

Yaqin Diao ◽

...

Keyword(s):

Nitrogen Deposition ◽

Taihu Lake ◽

Lake Basin ◽

Atmospheric Nitrogen Deposition ◽

Atmospheric Nitrogen ◽

Environmental Implications ◽

Taihu Lake Basin ◽

Headwater Catchment

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Methodology for classifying the ecosystem integrity of forests in Germany using quantified indicators

Environmental Sciences Europe ◽

10.1186/s12302-021-00478-y ◽

2021 ◽

Vol 33 (1) ◽

Author(s):

Martin Jenssen ◽

Stefan Nickel ◽

Winfried Schröder

Keyword(s):

Climate Change ◽

National Park ◽

Temporal Trends ◽

Water Flux ◽

Ecosystem Functions ◽

Specific Reference ◽

Atmospheric Nitrogen ◽

Complete Coverage ◽

Ecosystem Integrity ◽

Quantitative Indicators

Abstract Background Atmospheric deposition of nitrogen and climate change can have impacts on ecological structures and functions, and thus on the integrity of ecosystems and their services. Operationalization of ecosystem integrity is still an important desideratum. Results A methodology for classifying the ecosystem integrity of forests in Germany under the influence of climate change and atmospheric nitrogen deposition is presented. The methodology was based on 14 indicators for six ecosystem functions: habitat function, net primary function, carbon sequestration, nutrient and water flux, resilience. It allows assessments of ecosystem integrity changes by comparing current or prospective ecosystem states with ecosystem-type-specific reference states as described by quantitative indicators for 61 forest ecosystem types based on data before 1990. Conclusion The method developed enables site-specific classifications of ecosystem integrity as well as classifications with complete coverage and determinations of temporal trends as shown using examples from the Thuringian Forest and the “Kellerwald-Edersee” National Park (Germany).

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Selecting Biomonitors of Atmospheric Nitrogen Deposition: Guidelines for Practitioners and Decision Makers

Nitrogen ◽

10.3390/nitrogen2030021 ◽

2021 ◽

Vol 2 (3) ◽

pp. 308-320

Author(s):

D. Nayeli Martínez ◽

Edison A. Díaz-Álvarez ◽

Erick de la Barrera

Keyword(s):

Environmental Pollution ◽

Nitrogen Deposition ◽

Biodiversity Loss ◽

Decision Makers ◽

Economic Losses ◽

Atmospheric Nitrogen Deposition ◽

Atmospheric Nitrogen ◽

Nitrogen Emissions ◽

Vascular Epiphytes ◽

Ecophysiological Response

Environmental pollution is a major threat to public health and is the cause of important economic losses worldwide. Atmospheric nitrogen deposition is one of the most significant components of environmental pollution, which, in addition to being a health risk, is one of the leading drivers of global biodiversity loss. However, monitoring pollution is not possible in many regions of the world because the instrumentation, deployment, operation, and maintenance of automated systems is onerous. An affordable alternative is the use of biomonitors, naturally occurring or transplanted organisms that respond to environmental pollution with a consistent and measurable ecophysiological response. This policy brief advocates for the use of biomonitors of atmospheric nitrogen deposition. Descriptions of the biological and monitoring particularities of commonly utilized biomonitor lichens, bryophytes, vascular epiphytes, herbs, and woody plants, are followed by a discussion of the principal ecophysiological parameters that have been shown to respond to the different nitrogen emissions and their rate of deposition.

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Sources of Nitrogen for Winter Triticale (Triticosecale Wittm. ex A.Camus) Succeeding Pea (Pisum sativum L.)

Agronomy ◽

10.3390/agronomy11030527 ◽

2021 ◽

Vol 11 (3) ◽

pp. 527

Author(s):

Andrzej Wysokinski ◽

Izabela Lozak ◽

Beata Kuziemska

Keyword(s):

Root Nodule ◽

Crop Residues ◽

Spring Barley ◽

Sandy Soils ◽

High Availability ◽

Atmospheric Nitrogen ◽

15N Isotope ◽

Carbon And Nitrogen ◽

Winter Triticale ◽

Pisum Sativum L

Atmospheric nitrogen biologically reduced in legumes root nodule and accumulated in their postharvest residues may be of great importance as a source of this macronutrient for succeeding crops. The aim of the study was to determine nitrogen uptake by winter triticale from pea postharvest residues, including N fixed from atmosphere, using in the study fertilizer enriched with the 15N isotope. Triticale was grown without nitrogen fertilization at sites where the forecrops had been two pea cultivars (multi-purpose and field pea) and, for comparison, spring barley. The triticale crop succeeding pea took up more nitrogen from the soil (59.1%) and less from the residues of the forecrop (41.1%). The corresponding values where the forecrop was barley were 92.1% and 7.9%. In the triticale, the percentage of nitrogen derived from the atmosphere, introduced into the soil with pea crop residues amounted to 23.8%. The amounts of nitrogen derived from all sources in the entire biomass of triticale plants grown after harvesting of pea were similar for both pea cultivars. The cereal took up more nitrogen from all sources, when the soil on which the experiment was conducted had higher content of carbon and nitrogen and a greater amount of N was introduced with the pea residues. Nitrogen from pea residues had high availability for winter triticale as a succeeding crop cultivated on sandy soils.

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