Surprising relationships between soil pH and microbial biomass and activity in a northern hardwood forest

Ontman, Renata; Groffman, Peter M.; Driscoll, Charles T.; Cheng, Zhongqi

doi:10.1007/s10533-023-01031-0

Cited by 17 publications

(5 citation statements)

References 52 publications

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“…We found the same pattern in total and dissolved soil contents, which were also highest at Dav. This indicates for the mineral topsoil that microbial C, N, and S are positively related to soil content but negatively to pH, as shown in recent studies [27,53]. As the MBS contents are considered to be the most active S pool in S-turnover in soil, higher MBS contents indicate a greater S availability for higher plants [26].…”

Section: Ph Effects On Microbial Mineralizationmentioning

confidence: 65%

“…However, unexpected effects of pH changes on microbial biomass and activity in forest soils were also observed in northern hardwood forest plots, and underlying microbial processes are not completely understood [53]. Liming of acidified soils during recovery from pollution has a strong influence on the pH-dependence of microbial activity and therefore crucially impacts S mineralization processes.…”

Section: Ph Effects On Microbial Mineralizationmentioning

confidence: 99%

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Effects of Past Sulfur Deposition on the Soil Microbial Biomass at Spruce Forest Sites

Julich,

Feger

et al. 2024

Soil Systems

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During the last decades, forest soils in Central Europe recovered from former sulfur and acid deposition. As external S input into forests has strongly decreased and legacy S pools in the soils are diminishing, internal S cycling through mineralization will increasingly become important for ecosystem nutrition. However, it is not known how microbial biomass is affected by the S pool change in the formerly S surplus soils. Here, we present data on the status quo of C, N, and S in microbial biomass in relation to contents in mineral soil and organic layer. The results of forest soil in Eastern Germany (low and high liming), which is slowly recovering from former pollution, are compared to those of a site remote from air pollution in the Swiss Alps. The contents of C, N, and S in soil as well as in microbial biomass were clearly higher in the organic layer than in mineral topsoil at all sites. Despite the generally low content in the mineral A-horizon, the clean-air site showed indications of a more active S-turnover as compared to the high-pollution site. Liming at the high-pollution site improved the conditions for microbial growth (pH increase) in the organic layer resulting in more mobile S.

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Section: Ph Effects On Microbial Mineralizationmentioning

confidence: 65%

Section: Ph Effects On Microbial Mineralizationmentioning

confidence: 99%

Effects of Past Sulfur Deposition on the Soil Microbial Biomass at Spruce Forest Sites

Julich,

Feger

et al. 2024

Soil Systems

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“…In agreement with this, the random forest result showed that among multiple factors, soil N‐cycling traits (e.g., TN, BA, MBN, and denitrifying genes) significantly explained soil δ 15 N changes in wetter sites, which provides robust evidence that 15 N enrichment under relative drought conditions may largely result from strong soil N losses through microbe‐driven N transformations under high N availability conditions. Additionally, this microbe‐driven mechanism of soil 15 N enrichment is further supported by the pronounced contribution of soil pH to soil δ 15 N. As a key factor shaping microbial structure and function, soil pH strongly affects soil N‐cycling microbial communities (Ontman et al., 2023; Rousk et al., 2010; Scarlett et al., 2021). Our results showed that pH was the most pronounced driver of soil δ 15 N in wetter sites, with dramatically different pH values under different aridity conditions (Figure S5), indirectly highlighting the contribution of microbe‐driven N cycling to soil δ 15 N. Overall, these findings show that in wetter regions, soil 15 N closely tracked with soil N dynamics, suggesting that soil 15 N isotopes can accurately reflect soil N cycling and N availability in low aridity environments (Figure 5).…”

Section: Discussionmentioning

confidence: 99%

“…In agreement with this, the random forest result showed that among multiple factors, soil N-cycling traits (e.g., TN, BA, MBN, and denitrifying genes) significantly explained soil δ 15 N changes in wetter sites, which provides robust evidence that 15 N enrichment under relative drought conditions may largely result from strong soil N losses through microbe-driven N transformations under high N availability conditions. Additionally, this microbe-driven mechanism of soil 15 N enrichment is further supported by the pronounced contribution of soil pH to soil δ 15 N. As a key factor shaping microbial structure and function, soil pH strongly affects soil N-cycling microbial communities (Ontman et al, 2023;Rousk et al, 2010;Scarlett et al, 2021). Our with increasing aridity.…”

Section: Soil δ 15 N Patterns Along the Aridity Gradientmentioning

confidence: 90%

Aridity threshold for alpine soil nitrogen isotope signature and ecosystem nitrogen cycling

Mao,

Pan,

Song

et al. 2024

Global Change Biology

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Determination of tipping points in nitrogen (N) isotope (δ15N) natural abundance, especially soil δ15N, with increasing aridity, is critical for estimating N‐cycling dynamics and N limitation in terrestrial ecosystems. However, whether there are linear or nonlinear responses of soil δ15N to increases in aridity and if these responses correspond well with soil N cycling remains largely unknown. In this study, we investigated soil δ15N and soil N‐cycling characteristics in both topsoil and subsoil layers along a drought gradient across a 3000‐km transect of drylands on the Qinghai–Tibetan Plateau. We found that the effect of increasing aridity on soil δ15N values shifted from negative to positive with thresholds at aridity index (AI) = 0.27 and 0.29 for the topsoil and subsoil, respectively, although soil N pools and N transformation rates linearly decreased with increasing aridity in both soil layers. Furthermore, we identified markedly different correlations between soil δ15N and soil N‐cycling traits above and below the AI thresholds (0.27 and 0.29 for topsoil and subsoil, respectively). Specifically, in wetter regions, soil δ15N positively correlated with most soil N‐cycling traits, suggesting that high soil δ15N may result from the “openness” of soil N cycling. Conversely, in drier regions, soil δ15N showed insignificant relationships with soil N‐cycling traits and correlated well with factors, such as soil‐available phosphorus and foliage δ15N, demonstrating that pathways other than typical soil N cycling may dominate soil δ15N under drier conditions. Overall, these results highlight that different ecosystem N‐cycling processes may drive soil δ15N along the aridity gradient, broadening our understanding of N cycling as indicated by soil δ15N under changing drought regimes. The aridity threshold of soil δ15N should be considered in terrestrial N‐cycling models when incorporating 15N isotope signals to predict N cycling and availability under climatic dryness.

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“…The practice of burning plant residues and the use of mineral fertilizers may have contributed to the increase in soil acidity over time, as these practices reduce soil pH and favor the release of hydrogen ions (H+) and aluminum (Al + 3) (Chaves et al 2020). This continuous acidi cation process may be intensi ed due to base losses by leaching, dissolution reactions of CO 2 in the soil solution, dissociation of H + ions from organic and inorganic radicals by microbial activity(Ontman et al 2023).…”

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confidence: 99%

Physical and chemical soil quality and litter stock in agroforestry systems in the Eastern Amazon

de Souza,

Santos,

Martins

et al. 2024

Preprint

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The influence of biodiversity and age of agroforestry systems (AFS) on the provision of ecosystem services, such as nutrient cycling, needs to be better understood to support management practices that promote such services. This study aimed to quantify and compare litter stock and the physical and chemical attributes of soil in four AFSs with different ages and arrangements to a secondary forest (FLO) in the Eastern Amazon. Litter stock did not differ among the AFSs, but the youngest AFS was lower (5.73 ± 1.04 Mg ha− 1) than in FLO (11.42 ± 2.44 Mg ha− 1). Similarities were found between FLO and the oldest AFS for most of the soil chemical attributes. The soil pH in AFSs was higher than in FLO in the surface layer, and the organic matter content of FLO did not differ from 2 and 51-year-old AFSs. The Al content and aluminum saturation of younger and 26 years-old AFSs were lower than in FLO. Particle density and total porosity did not differ among ecosystems, while soil density in the two younger AFSs was higher than in FLO. According to PCA results, variables such as organic matter, CECpH7, H + Al, Al content, and m % tended to be higher in FLO and oldest AFS. It was evident that the maturity and diversity of AFSs are relevant factors for Amazonian agroforests, as they offer positive impacts on ecosystem functionality, such as nutrient cycling and water retention.

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Surprising relationships between soil pH and microbial biomass and activity in a northern hardwood forest

Cited by 17 publications

References 52 publications

Effects of Past Sulfur Deposition on the Soil Microbial Biomass at Spruce Forest Sites

Effects of Past Sulfur Deposition on the Soil Microbial Biomass at Spruce Forest Sites

Aridity threshold for alpine soil nitrogen isotope signature and ecosystem nitrogen cycling

Physical and chemical soil quality and litter stock in agroforestry systems in the Eastern Amazon

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