Soil texture controls added organic matter mineralization by regulating soil moisture—evidence from a field experiment in a maritime climate

Li, Haichao; Bulcke, Jan Van den; Mendoza, Orly; Deroo, Heleen; Haesaert, Geert; Dewitte, Kevin; Sleutel, Steven

doi:10.1016/j.geoderma.2021.115690

Cited by 24 publications

(7 citation statements)

References 59 publications

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“…In relation to organic soil, there was an inverse relationship. The content of C org in mineral soil was statistically significantly correlated with the proportion of silt (r-Pearson = 0.3680; p < 0.01) and clay (r-Pearson = 0.2682; p < 0.05) -which is a generally observed regularity for soils under similar climatic conditions (Li et al, 2022).…”

Section: Resultsmentioning

confidence: 61%

Quantification of nitrates leaching from grassland soils in winter using the Burns model

Pietrzak,

Urbaniak

2024

Journal of Water and Land Development

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This paper presents the results of a study on the level of nitrate leaching from the 0–30 cm layer of grassland (GL) soil in the Lublin Voivodship during the winters of 2018/2019, 2019/2020 and 2020/2021. The amounts of leached nitrates were determined using the Burns model. For the calculations based on this model – directly and indirectly, the results determination of residual nitrate nitrogen, texture and organic matter in GL soils, obtained within the framework of agricultural monitoring of soils by the National Chemical and Agricultural Station (KSChR), and results of system meteorological measurements conducted by the Institute of Meteorology and Water Management – National Research Institute (IMGW-PIB) were used. The analysed soil samples were taken from 39 permanent control and measurement grassland sites. The research discovered in particular that: – the average leaching of nitrate nitrogen from GL mineral soil in the three analysed periods was 16.2 and 5.1 kg N∙ha–1 from organic soil; – on average, in autumn during the entire study period, 55.3% of NO3-N leached from the 0–30 cm layer of GL mineral soil, and 27.3% from organic soil; – among different agronomic categories of mineral soil, the highest leaching of NO3-N was recorded from medium soil (17.4 kg N∙ha–1) and the lowest from heavy soil (11.5 kg N∙ha–1); – individually determined values of NO3-N leaching from soil varied significantly from 0 to 68.5 kg N∙ha–1 for mineral soil and from 0.1 to 23.65 kg N∙ha–1 for organic soil.

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Section: Resultsmentioning

confidence: 61%

Quantification of nitrates leaching from grassland soils in winter using the Burns model

Pietrzak,

Urbaniak

2024

Journal of Water and Land Development

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“…The finer soils are associated with the higher stabilization of soil organic matter (SOM) and total %C storage ( 64 ); therefore, we did not observe differences between ecotypes in the Silt Loam soil of Carbondale or Hays. In the sandy soil of Manhattan, the differences in the soil carbon deposit would become more distinct between ecotypes and result in higher wet ecotypic carbon deposits due to the wet plant host having a higher overall biomass ( 64 , 65 ). Additionally, although the root C:N strongly differed among the ecotypes across sites ( 66 ), our data provided no support for differences in the rhizosphere soil %N among the ecotypes, suggesting that the rhizosphere soils are resistant to the N rhizodeposits, and such changes in the rhizosphere soil may take longer than the decade that the experiment has been in place ( 67 , 68 ).…”

Section: Resultsmentioning

confidence: 99%

Home-field advantage affects the local adaptive interaction betweenAndropogon gerardiiecotypes and root-associated bacterial communities

Kazarina,

Sarkar,

Thapa

et al. 2023

Microbiol Spectr

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Due to climate change, drought frequencies and severities are predicted to increase across the United States. Plant responses and adaptation to stresses depend on plant genetic and environmental factors. Understanding the effect of those factors on plant performance is required to predict species’ responses to environmental change. We used reciprocal gardens planted with distinct regional ecotypes of the perennial grass Andropogon gerardii adapted to dry, mesic, and wet environments to characterize their rhizosphere communities using 16S rRNA metabarcode sequencing. Even though the local microbial pool was the main driver of these rhizosphere communities, the significant plant ecotypic effect highlighted active microbial recruitment in the rhizosphere, driven by ecotype or plant genetic background. Our data also suggest that ecotypes planted at their homesites were more successful in recruiting rhizosphere community members that were unique to the location. The link between the plants’ homesite and the specific local microbes supported the “home field advantage” hypothesis. The unique homesite microbes may represent microbial specialists that are linked to plant stress responses. Furthermore, our data support ecotypic variation in the recruitment of congeneric but distinct bacterial variants, highlighting the nuanced plant ecotype effects on rhizosphere microbiome recruitment. These results improve our understanding of the complex plant host–soil microbe interactions and should facilitate further studies focused on exploring the functional potential of recruited microbes. Our study has the potential to aid in predicting grassland ecosystem responses to climate change and impact restoration management practices to promote grassland sustainability. IMPORTANCE In this study, we used reciprocal gardens located across a steep precipitation gradient to characterize rhizosphere communities of distinct dry, mesic, and wet regional ecotypes of the perennial grass Andropogon gerardii . We used 16S rRNA amplicon sequencing and focused oligotyping analysis and showed that even though location was the main driver of the microbial communities, ecotypes could potentially recruit distinct bacterial populations. We showed that different A. gerardii ecotypes were more successful in overall community recruitment and recruitment of microbes unique to the “home” environment, when growing at their “home site.” We found evidence for “home-field advantage” interactions between the host and host–root-associated bacterial communities, and the capability of ecotypes to recruit specialized microbes that were potentially linked to plant stress responses. Our study aids in a better understanding of the factors that affect plant adaptation, improve management strategies, and predict grassland function under the changing climate.

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“…In turn, it is necessary to highlight the importance of inherited physical factors which do not present the same temporal dynamics. Particularly, soil texture presents a permanent limiting factor regarding low moisture retention capacity (Haichao et al, 2022) and wind erosion risk in these lands. This is evident, to different extents, depending on changes in rainfall as well as uses and management (Richardson and Sadler, (2022), it is frequent to observe that the different spatial composition and configuration of the current anthropogenic landscape is not related with the land potential, which may increase the risk of environmental degradation.…”

Section: La Pampa Province Areamentioning

confidence: 99%

Avaliação de terras sob diferentes cenários climáticos na sub-região Pampa Arenosa, Argentina

Cassani

Pérez²

2023

Rev. Bras. Geog. Fis.

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Since the 70´s, Pampa Arenosa Subregion has experienced a rise in its water regime, allowing a greater area for dryland farming. Given farming intensification, assessing lands on the basis of rainfall variations is a fundamental strategic tool for planning. The objective of this work is to highlight the importance of different climate scenarios when determining Productivity Index in the Pampa Arenosa Subregion, Argentina. The study area was located in the Northwest of Buenos Aires and the East of La Pampa Province. Monthly precipitation data for the period 1921-2020 was used. Climate scenarios were determined according to changes in the values of mean rainfall using Hubert´s Hydrometeorological temporal segmentation test. Edaphic information was obtained from soil charts provided by INTA 1:50000 and the Natural Resource Inventory of La Pampa 1:500000. Resorting to Hubert´s test, several scenarios were proposed with different starting point for the macro climate conditions (H) of Productivity Index. Changes in annual rainfall mean values were detected in regions of Pampa Arenosa. The lands were classified by Productivity Index, which increased as rainfall became higher, reaching its maximum climate expression during the wet period after a positive abrupt change. Segmentation results of rainfall annual series for Pampa Arenosa Sub region, using Hubert´s method, allowed defining dry and wet subperiods, for IP estimation. In the Pampa region, climate variability is represented by the succession of dry and wet periods, and their extreme phenomena have important social and economic impacts.

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Soil texture controls added organic matter mineralization by regulating soil moisture—evidence from a field experiment in a maritime climate

Cited by 24 publications

References 59 publications

Quantification of nitrates leaching from grassland soils in winter using the Burns model

Quantification of nitrates leaching from grassland soils in winter using the Burns model

Home-field advantage affects the local adaptive interaction betweenAndropogon gerardiiecotypes and root-associated bacterial communities

Avaliação de terras sob diferentes cenários climáticos na sub-região Pampa Arenosa, Argentina

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