FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2022147049> ?p ?o ?g. }

• W2022147049 endingPage "2323" @default.
• W2022147049 startingPage "2317" @default.
• W2022147049 abstract "Reduction of nitrous oxide (N2O) to dinitrogen (N2) by denitrification in soils is of outstanding ecological significance since it is the prevailing natural process converting reactive nitrogen back into inert molecular dinitrogen. Furthermore, the extent to which N2O is reduced to N2 via denitrification is a major regulating factor affecting the magnitude of N2O emission from soils. However, due to methodological problems in the past, extremely little information is available on N2 emission and the N2:N2O emission ratio for soils of terrestrial ecosystems. In this study, we simultaneously determined N2 and N2O emissions from intact soil cores taken from a mountainous beech forest ecosystem. The soil cores were taken from plots with distinct differences in microclimate (warm-dry versus cool-moist) and silvicultural treatment (untreated control versus heavy thinning). Due to different microclimates, the plots showed pronounced differences in pH values (range: 6.3–7.3). N2O emission from the soil cores was generally very low (2.0 ± 0.5–6.3 ± 3.8 μg N m−2 h−1 at the warm-dry site and 7.1 ± 3.1–57.4 ± 28.5 μg N m−2 h−1 at the cool-moist site), thus confirming results from field measurements. However, N2 emission exceeded N2O emission by a factor of 21 ± 6–220 ± 122 at the investigated plots. This illustrates that the dominant end product of denitrification at our plots and under the given environmental conditions is N2 rather than N2O. N2 emission showed a huge variability (range: 161 ± 64–1070 ± 499 μg N m−2 h−1), so that potential effects of microclimate or silvicultural treatment on N2 emission could not be identified with certainty. However, there was a significant effect of microclimate on the magnitude of N2O emission as well as on the mean N2:N2O emission ratio. N2:N2O emission ratios were higher and N2O emissions were lower for soil cores taken from the plots with warm-dry microclimate as compared to soil cores taken from the cool-moist microclimate plots. We hypothesize that the increase in the N2:N2O emission ratio at the warm-dry site was due to higher N2O reductase activity provoked by the higher soil pH value of this site. Overall, the results of this study show that the N2:N2O emission ratio is crucial for understanding the regulation of N2O fluxes of the investigated soil and that reliable estimates of N2 emissions are an indispensable prerequisite for accurately calculating total N gas budgets for the investigated ecosystem and very likely for many other terrestrial upland ecosystems as well." @default.
• W2022147049 created "2016-06-24" @default.
• W2022147049 creator A5011061423 @default.
• W2022147049 creator A5012914299 @default.
• W2022147049 creator A5037565718 @default.
• W2022147049 creator A5057305370 @default.
• W2022147049 creator A5065089674 @default.
• W2022147049 date "2008-09-01" @default.
• W2022147049 modified "2023-10-02" @default.
• W2022147049 title "Dinitrogen emissions and the N2:N2O emission ratio of a Rendzic Leptosol as influenced by pH and forest thinning" @default.
• W2022147049 cites W167651521 @default.
• W2022147049 cites W1991102358 @default.
• W2022147049 cites W2006438810 @default.
• W2022147049 cites W2013987876 @default.
• W2022147049 cites W2027913716 @default.
• W2022147049 cites W2054546320 @default.
• W2022147049 cites W2060045323 @default.
• W2022147049 cites W2083307126 @default.
• W2022147049 cites W2097004990 @default.
• W2022147049 cites W2098103028 @default.
• W2022147049 cites W2104982529 @default.
• W2022147049 cites W2105025687 @default.
• W2022147049 cites W2107606016 @default.
• W2022147049 cites W2131407861 @default.
• W2022147049 cites W2137987558 @default.
• W2022147049 cites W2148126824 @default.
• W2022147049 cites W2149352713 @default.
• W2022147049 cites W2161071045 @default.
• W2022147049 cites W2171070596 @default.
• W2022147049 cites W2180779804 @default.
• W2022147049 cites W2913311670 @default.
• W2022147049 cites W3176736113 @default.
• W2022147049 cites W366392033 @default.
• W2022147049 doi "https://doi.org/10.1016/j.soilbio.2008.05.009" @default.
• W2022147049 hasPublicationYear "2008" @default.
• W2022147049 type Work @default.
• W2022147049 sameAs 2022147049 @default.
• W2022147049 citedByCount "99" @default.
• W2022147049 countsByYear W20221470492012 @default.
• W2022147049 countsByYear W20221470492013 @default.
• W2022147049 countsByYear W20221470492014 @default.
• W2022147049 countsByYear W20221470492015 @default.
• W2022147049 countsByYear W20221470492016 @default.
• W2022147049 countsByYear W20221470492017 @default.
• W2022147049 countsByYear W20221470492018 @default.
• W2022147049 countsByYear W20221470492019 @default.
• W2022147049 countsByYear W20221470492020 @default.
• W2022147049 countsByYear W20221470492021 @default.
• W2022147049 countsByYear W20221470492022 @default.
• W2022147049 countsByYear W20221470492023 @default.
• W2022147049 crossrefType "journal-article" @default.
• W2022147049 hasAuthorship W2022147049A5011061423 @default.
• W2022147049 hasAuthorship W2022147049A5012914299 @default.
• W2022147049 hasAuthorship W2022147049A5037565718 @default.
• W2022147049 hasAuthorship W2022147049A5057305370 @default.
• W2022147049 hasAuthorship W2022147049A5065089674 @default.
• W2022147049 hasConcept C107872376 @default.
• W2022147049 hasConcept C110872660 @default.
• W2022147049 hasConcept C116119225 @default.
• W2022147049 hasConcept C130047971 @default.
• W2022147049 hasConcept C159390177 @default.
• W2022147049 hasConcept C159750122 @default.
• W2022147049 hasConcept C178790620 @default.
• W2022147049 hasConcept C185592680 @default.
• W2022147049 hasConcept C18903297 @default.
• W2022147049 hasConcept C2776500793 @default.
• W2022147049 hasConcept C2777573673 @default.
• W2022147049 hasConcept C2781353100 @default.
• W2022147049 hasConcept C32957820 @default.
• W2022147049 hasConcept C39432304 @default.
• W2022147049 hasConcept C49045045 @default.
• W2022147049 hasConcept C537208039 @default.
• W2022147049 hasConcept C73593433 @default.
• W2022147049 hasConcept C86803240 @default.
• W2022147049 hasConceptScore W2022147049C107872376 @default.
• W2022147049 hasConceptScore W2022147049C110872660 @default.
• W2022147049 hasConceptScore W2022147049C116119225 @default.
• W2022147049 hasConceptScore W2022147049C130047971 @default.
• W2022147049 hasConceptScore W2022147049C159390177 @default.
• W2022147049 hasConceptScore W2022147049C159750122 @default.
• W2022147049 hasConceptScore W2022147049C178790620 @default.
• W2022147049 hasConceptScore W2022147049C185592680 @default.
• W2022147049 hasConceptScore W2022147049C18903297 @default.
• W2022147049 hasConceptScore W2022147049C2776500793 @default.
• W2022147049 hasConceptScore W2022147049C2777573673 @default.
• W2022147049 hasConceptScore W2022147049C2781353100 @default.
• W2022147049 hasConceptScore W2022147049C32957820 @default.
• W2022147049 hasConceptScore W2022147049C39432304 @default.
• W2022147049 hasConceptScore W2022147049C49045045 @default.
• W2022147049 hasConceptScore W2022147049C537208039 @default.
• W2022147049 hasConceptScore W2022147049C73593433 @default.
• W2022147049 hasConceptScore W2022147049C86803240 @default.
• W2022147049 hasIssue "9" @default.
• W2022147049 hasLocation W20221470491 @default.
• W2022147049 hasOpenAccess W2022147049 @default.
• W2022147049 hasPrimaryLocation W20221470491 @default.
• W2022147049 hasRelatedWork W1000728162 @default.
• W2022147049 hasRelatedWork W2033423533 @default.

• next