In situ <sup>15</sup>N labeling experiment reveals different long‐term responses to ammonium and nitrate inputs in N‐saturated subtropical forest

Liu, Wenjing; Yu, Longfei; Zhang, Ting; Kang, Ronghua; Zhu, Jing; Mulder, Jan; Huang, Yongmei; Duan, Lei

doi:10.1002/2017jg003963

Cited by 32 publications

(36 citation statements)

References 60 publications

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“…The importance of NO 3 − leaching is supported by the significant recovery of 15 N in the deeper AB horizon (Figure S5, supporting information) . Significant loss of labeled NO 3 − from the soil was also observed in a recent study at the same site . In addition to leaching, the atom% 15 N in NO 3 − also declined due to dilution by NO 3 − produced from nitrification of non‐labeled NH 4 + , which showed stable atom% 15 N close to natural abundance throughout the experiment (Figures B and D).…”

Section: Resultssupporting

confidence: 68%

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Nitrification is the primary source for NO in N‐saturated subtropical forest soils: Results from in situ¹⁵N labeling

Kang

Dörsch

et al. 2020

Rapid Comm Mass Spectrometry

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Rationale Acidic subtropical forest soils that receive high atmospheric nitrogen (N) deposition have been identified as important sources of nitric oxide (NO). The relative importance of major processes producing NO is unclear. Methods To partition NO sources, we conducted an in situ tracing experiment with 15NH4NO3 and NH415NO3 in well‐drained acid soils of an N‐saturated subtropical forest in Chongqing, southwest China. Results In the 15NH4NO3 treatment, the 15N signature of NO emitted from the foot of the hillslope (Lower site) was similar to that of the NH4+ pool, indicating predominant autotrophic nitrification for NO formation. In the NH415NO3 treatment, the 15N enrichment of NO was smaller than that of the NO3− pool, suggesting minor contribution of denitrification to NO production (~15%). Conclusions Nitrification is the main process responsible for NO emissions, even in monsoonal summers when soil water‐filled pore space values are relatively high.

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Section: Resultssupporting

confidence: 68%

“…19 Significant loss of labeled NO 3 − from the soil was also observed in a recent study at the same site. 34 In addition to leaching, the atom% 15 production, 19 we show here that nitrification is the main source of NO.…”

Section: No Emission Rates Measurements and Modelingmentioning

confidence: 64%

Nitrification is the primary source for NO in N‐saturated subtropical forest soils: Results from in situ¹⁵N labeling

Kang

Dörsch

et al. 2020

Rapid Comm Mass Spectrometry

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“…It should be noted that nitrate leaching did not cease in this study, indicating that N saturation should still exist under current N deposition. In actuality, previous studies showed clear N saturation at TSP, with nearly all added N leached by soil water (Huang et al, ; Liu, Yu, et al, ). It is believed that N leaching only begins to increase significantly after the soil reaches N‐saturation (Aber & Magill ; Fang et al, ; Huang et al, ; Larssen et al, ).…”

Section: Discussionmentioning

confidence: 72%

“…Moreover, in addition to acidification, N saturation caused by increased N deposition may result in the eutrophication of soil and water, the emission of N 2 O (a potent greenhouse gas that is increasingly important in the destruction of stratospheric ozone; Fang et al, ; Li et al, ; Ravishankara et al, ), and reduced biodiversity and forest growth (Aber et al, ; Aber et al, ; Kreutzer et al, ; Lu et al, ; Pardo et al, ). Therefore, an “explosion” in N effect studies has occurred in Asia, especially in China, during the past few decades, both in forests and grasslands (Bai et al, ; Chen et al, ; Guo et al, ; Huang et al, ; Li et al, ; Liu, Yu, et al, ; Liu, Zhang, et al, ; Lu et al, ; Wei et al, ).…”

Section: Introductionmentioning

confidence: 99%

“…A rapid reduction in the soil N leaching was expected, but no significant change was expected in soil water pH due to buffering by Al mobilization and SO 4 2− sorption (Huang et al, ). Based on a 15 N labeling experiment, Liu, Yu, et al () suggested that some net sorption of NH 4 + may occur, probably due to accumulation in soil organic matter (including in microorganisms). Therefore, we also hypothesize that ending NH 4 NO 3 fertilization should result in lower NO 3 − leaching than in the reference plots receiving ambient deposition.…”

Section: Introductionmentioning

confidence: 99%

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A Sharp Decline in Nitrogen Input in a N‐Saturated Subtropical Forest Causes an Instantaneous Reduction in Nitrogen Leaching

Xie

Zhang

et al. 2018

JGR Biogeosciences

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In China, as in other parts of the world, the emission and deposition of reactive nitrogen (N) have been reduced in recent years. Several decades of elevated N deposition in southwest China (40 to 60 kg ha À1 year À1 ) have resulted in extreme cases of N saturation, where N outputs are nearly equal to N inputs. Doubling N inputs using either NH 4 NO 3 or NaNO 3 fertilizer in a subtropical forest in Tieshanping, near Chongqing city in southwest China, caused an immediate doubling of N leaching (as NO 3 À ). Reducing N inputs to ambient atmospheric deposition levels after 10 years of fertilization led to a rapid decrease in soil water NO 3 À concentration to levels similar to those in the reference plots that had not receive N fertilizer application. NO 3 À leaching via the soil water in the NH 4 NO 3 plots was even lower than that in the NaNO 3 plots or the reference plots, confirming the finding of a previous N-fertilizing experiment that found that NH 4 + deposition, in contrast to NO 3 À deposition, increased N retention in the forest ecosystem. The N sink remained for at least 2 years after the cessation of N addition. Even with reduced N inputs, ambient atmospheric N deposition caused significant acidification, buffered partly by SO 4 2À sorption. Therefore, further abatement of reactive N emissions is necessary in the future.NH 4 + deposition has been less significant because of technical, economic, and regulatory difficulties in the control of NH 3 emissions (Hanssen, 2001; NADP, 2010). N deposition reduction has had some effects, including declines in soil N leaching (Akselsson et al.

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Retention and partitioning of 15N-labeled deposited N in a tropical plantation forest

Gurmesa

Gundersen

et al. 2021

Biogeochemistry

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The effects of deposited nitrogen (N) on forest ecosystems largely depend on the amount of N retained in the ecosystems and its partitioning among ecosystem pools. However, our understanding of the capacity of tropical plantations to retain deposited N is limited. To evaluate the retention of deposited N in a human-disturbed pine plantation in southern China and compare the result with previous findings in an adjacent old-growth forest, we added 15 N-tracer monthly to the forest floor for one year and determined its recovery in ecosystem compartments four months after the last addition. We monitored 15 N recoveries in soil solution monthly to quantify leaching losses. The pine forest retained about 58 ± 5% of the 15 N-labeled deposited N, which is lower than that reported in the adjacent old-growth forest (72 ± 6%). Both forests experience chronic N deposition (recently measured at 51 kg N ha -1 yr -1 ) and we attribute the difference in retention to effects of previous disturbance mainly understory and litter harvesting in the pine plantation. Only 3 kg N ha -1 yr -1 (5% of the 15 N-labeled deposited N) out of the measured total leaching (54 kg N ha -1 yr -1 ) originated from deposited (and labeled) N from the measurement year, suggesting that N leaching is dominated by unlabeled N sources. Furthermore, results from our study and other similar

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In situ ¹⁵N labeling experiment reveals different long‐term responses to ammonium and nitrate inputs in N‐saturated subtropical forest

Cited by 32 publications

References 60 publications

Nitrification is the primary source for NO in N‐saturated subtropical forest soils: Results from in situ¹⁵N labeling

Nitrification is the primary source for NO in N‐saturated subtropical forest soils: Results from in situ¹⁵N labeling

A Sharp Decline in Nitrogen Input in a N‐Saturated Subtropical Forest Causes an Instantaneous Reduction in Nitrogen Leaching

Retention and partitioning of 15N-labeled deposited N in a tropical plantation forest

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In situ 15N labeling experiment reveals different long‐term responses to ammonium and nitrate inputs in N‐saturated subtropical forest

Cited by 32 publications

References 60 publications

Nitrification is the primary source for NO in N‐saturated subtropical forest soils: Results from in situ15N labeling

Nitrification is the primary source for NO in N‐saturated subtropical forest soils: Results from in situ15N labeling

A Sharp Decline in Nitrogen Input in a N‐Saturated Subtropical Forest Causes an Instantaneous Reduction in Nitrogen Leaching

Retention and partitioning of 15N-labeled deposited N in a tropical plantation forest

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In situ ¹⁵N labeling experiment reveals different long‐term responses to ammonium and nitrate inputs in N‐saturated subtropical forest

Nitrification is the primary source for NO in N‐saturated subtropical forest soils: Results from in situ¹⁵N labeling

Nitrification is the primary source for NO in N‐saturated subtropical forest soils: Results from in situ¹⁵N labeling