An Assessment of Climate Induced Increase in Soil Water Availability for Soil Bacterial Communities Exposed to Long-Term Differential Phosphorus Fertilization

Randall, Kate C.; Brennan, Fiona; Clipson, Nicholas; Creamer, Rachel; Griffiths, Bryan S.; Storey, Sean; Doyle, Evelyn

doi:10.3389/fmicb.2020.00682

Cited by 3 publications

(3 citation statements)

References 117 publications

(141 reference statements)

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“…Sandy soils require more frequent irrigation than silty soils with larger PASW storage capacity. For natural systems, the concept of PASW has been used in ecological studies (Liu et al., 2009; Randall et al., 2020) to investigate how soil modulates climatic inputs or forcing affecting vegetation. In other words, PASW is not used for “design” or crop selection, but for interpretation of natural vegetation response to climatic conditions or changes in rainfall patterns.…”

Section: Discussionmentioning

confidence: 99%

Global Mapping of Potential and Climatic Plant‐Available Soil Water

Gupta,

Lehmann,

Bickel

et al. 2023

J Adv Model Earth Syst

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The estimation of plant‐available soil water (PASW) is essential to quantify transpiration fluxes, the onset of heatwaves, irrigation water management, land‐use decisions, vegetation ecology, and land surface memory in climate models. PASW is the amount of stored water available for plant use. It is broadly defined as the difference between soil water content at field capacity (FC) and wilting point (WP) in the root zone. The limiting states of FC and WP are linked to gravitational drainage and plant physiology and are often deduced from soil water characteristics at prescribed matric potentials (−3.3 and −150 m for FC and WP, respectively). Evidence suggests that static definition of FC at a constant matric potential ignores dynamic effects on FC attainment affected by soil and climate. Here, we revise the definition of PASW by considering (a) soil‐specific dynamic effects and (b) local climate effects of evaporation and rainfall frequency on PASW. The new global PASW maps benefit from state‐of‐the‐art soil maps, water characteristic parameterization, and incorporation of dynamic definition of FC. For completeness we provide static and dynamic PASW estimates. Globally, ice‐free soils store up to 19,941 km3 of water in the top 1 m (representing 18% of annual terrestrial precipitation). Adjusted for local climatic conditions, global PASW storage rarely exceeds 14,853 km3 per year highlighting the need for multiple refilling of soil profiles. Differences between potential and climatic PASW are manifested primarily in arid regions (where soil profiles are rarely filled to capacity) whereas in humid regions differences in PASW storage are minor.

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Section: Discussionmentioning

confidence: 99%

Global Mapping of Potential and Climatic Plant‐Available Soil Water

Gupta,

Lehmann,

Bickel

et al. 2023

J Adv Model Earth Syst

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“…Under controlled environments, P fertilization has been found to have a more prominent effect on acid and alkaline phosphatase enzyme activities than soil moisture or temperature (Randall et al, 2020;Sun et al, 2018). However, field studies conducted in intensively managed agroecosystems and grasslands showed that seasonal changes in soil moisture and temperature had a more significant impact on alkaline phosphatase enzyme activity compared with P fertilization (Shi et al, 2013(Shi et al, , 2020.…”

Section: Effects Of Seasonal Conditions On Organic Soil P Cyclingmentioning

confidence: 99%

“…Perrott et al (1992) found that microbial biomass P increased with increasing soil moisture in a low P grassland soil, whereas He et al (1997) described no clear relationship between microbial biomass P and air temperature in both unfertilized and P fertilized pasture systems in the United Kingdom. On the other hand, Randall et al (2020) pointed out a significant response of acid phosphatase activity to historical soil P status but not of water availability in soils taken from a long‐term P fertilization experiment under pastures. A more refined understanding of P immobilization and mineralization processes as affected by soil moisture, temperature, and P availability is needed to better predict organic P cycling, especially under future scenarios of climate change.…”

Section: Introductionmentioning

confidence: 99%

Effects of long‐term phosphorus fertilizer inputs and seasonal conditions on organic soil phosphorus cycling under grazed pasture

Touhami

Condron

McDowell

et al. 2022

Soil Use and Management

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Soil microbes and phosphatase enzymes play a critical role in organic soil phosphorus (P) cycling. However, how long-term P inputs influence microbial P transformations and phosphatase enzyme activity under grazed pastures remains unclear. We collected top-soil (0-75 mm) from a grazed pasture receiving contrasting P inputs (control, 188 kg ha −1 year −1 of single super phosphate [SSP], and 376 kg ha −1 year −1 of SSP) for more than 65 years. Olsen P, microbial biomass P, and acid and alkaline phosphatase enzyme activities were measured regularly over a 2-year period. Pasture dry matter and soil chemical properties were also investigated. Results showed that long-term P inputs significantly increased pasture dry matter, total N, and the concentrations of NO − 3 -N but significantly decreased soil pH and the concentrations of NH + 4 -N. Total C was not affected by P fertilization. Although Olsen P significantly increased with increasing long-term P inputs, microbial biomass P was similar under P fertilized treatments. Long-term P inputs decreased acid phosphatase activity but increased alkaline phosphatase activity. Microbial biomass P was similar across seasons in the control but decreased in spring and autumn while increased in summer and winter under P fertilized treatments. Acid and alkaline phosphatase activities were significantly affected by season and followed similar seasonal trends being maximum in summer and minimum in winter regardless of P treatment. Correlation and principal component analysis revealed that acid and alkaline phosphatase activities were significantly positively correlated with soil temperature and significantly negatively correlated with soil moisture. In contrast, Olsen P and microbial biomass P were weakly correlated with environmental conditions. The findings of this study highlight the intertwined relationship between organic P cycling and the availability of C and N in soil systems and the need to integrate both soil moisture and temperature in models predicting organic P mineralization, especially in the context of global climate change.

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