Research on Occurrence and Development of Pasture Drought Events in Alpine Grassland using the Drought Threshold

Tiaofeng, Zhang; Li, Lin; Hu, Xiao; Hong-mei, LI

doi:10.5194/nhess-2018-305

Cited by 2 publications

(2 citation statements)

References 5 publications

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“…However, the relative abundance of Ascomycota in the APRI+40%FMC treatment was greater than that in the EW + 40%FMC treatment. This may be because the soil of APRI +40% FMC was the most arid, leading to increased drought stress on alfalfa and increased root exudates ( Walker et al, 2003 ; Jones et al, 2009 ), thereby increasing the abundance of Ascomycota in the rhizosphere soil ( Zhang et al, 2018 ; Li et al, 2021 ). As drought severity increased, the relative abundance of unclassified K fungi in the alfalfa rhizosphere soil significantly increased, suggesting that these fungal taxa may be more drought-tolerant fungi hidden in the soil and may reorganize microbial structures in long-term arid soils.…”

Section: Discussionmentioning

confidence: 99%

Impact of alternate partial root-zone irrigation on the rhizosphere microbiota of alfalfa plants inoculated with rhizobia

Zou,

Xin,

Wang

et al. 2024

Front. Microbiol.

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Water is an important constraint on alfalfa (Medicago sativa) production in arid and semiarid areas, and alternate irrigation in root areas has water-saving potential for alfalfa production. To investigate the impact of alternate partial root-zone irrigation (APRI) on the rhizosphere soil microorganisms of alfalfa, this study subjected alfalfa plants to different irrigation methods and irrigation levels. The growth status and rhizosphere soil microbial community diversity of alfalfa plants under alternate root-zone watering treatment were analyzed through laboratory experiments and high-throughput sequencing. The results showed that at soil moisture levels of 80% field moisture capacity (FMC) and 60% FMC, APRI had no significant impact on the biomass or nodule number of alfalfa. However, 40% FMC significantly reduced the individual plant dry weight, chlorophyll content, and nodule number of the alfalfa plants. APRI increased the relative abundance of Actinomycetes in the alfalfa rhizosphere soil. Moreover, at 60% FMC, the MBC and MBN of rhizosphere, relative abundance of Actinobacteria and unclassified K fungi and Chao 1 index of bacteria significantly increased under APRI treatment. While relative abundance of Ascomycetes and Proteobacteria in the alfalfa rhizosphere significantly reduced under 60% FMC + APRI treatment. In summary, under the same irrigation conditions, APRI did not significantly affect the growth of alfalfa in the short term. And 60%FMC + APRI treatment did significantly affect the groups, structure and diversity of the rhizosphere soil microbial communities.

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Section: Discussionmentioning

confidence: 99%

Impact of alternate partial root-zone irrigation on the rhizosphere microbiota of alfalfa plants inoculated with rhizobia

Zou,

Xin,

Wang

et al. 2024

Front. Microbiol.

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“…2014 overall was a very rainy year. As Zhang et al (2018) highlighted, the durations of drought impacts on vegetation are mostly correlated with initial soil moisture and previous precipitation. Our results confirm this behaviour, showing a relatively good vegetation condition in 2015.…”

Section: Discussionmentioning

confidence: 99%

Grassland ecosystems resilience to drought: The role of surface water ponds

et al. 2023

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Currently, grassland ecosystems' stability is facing severe challenges due to climate variability and the increased frequency and intensity of extreme droughts. In many grasslands worldwide, closed‐basin ponds supply various ecosystem services by collecting rainfall and runoff. These ponds may provide a significant opportunity to mitigate climate change pressures and improve the resilience of grasslands. Nevertheless, their conservation is hampered by problems auditing these small and dynamic features. Understanding the dynamics that characterise the interactions of ponds and grassland vegetation with climate changes is, therefore, a priority for better quantifying future impacts of climate change on managed‐land systems. This study investigated variations of grassland vegetation quality from 2001 to 2021 in Lessinia Regional Park, a pre‐alpine historical rural landscape in northern Italy. We combined multi‐source data, weather information, and satellite‐derived vegetation quality indices. The work focuses the analysis using a ‘pond landscape dominance’ index, calculated as a proxy of hydrologic connectivity, to illustrate the function of ponds in regulating vegetation. We provided an unprecedented mapping of 459 ponds across the whole area. The results show a progressively decreasing vegetation quality in Lessinia, following rainfall and temperature variability. Overall, however, the analysis highlighted the benefit of water extent and closeness to ponds in providing higher resistance of grasslands against drought, especially during the driest study years. These results demonstrate that this approach has great potential for monitoring the resistance of grasslands in response to drought over large regions. This study supports the importance of identifying multiple co‐benefits and ecosystem services related to ponds, which can help communities cope with climate change and environmental challenges.

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Research on Occurrence and Development of Pasture Drought Events in Alpine Grassland using the Drought Threshold

Cited by 2 publications

References 5 publications

Impact of alternate partial root-zone irrigation on the rhizosphere microbiota of alfalfa plants inoculated with rhizobia

Impact of alternate partial root-zone irrigation on the rhizosphere microbiota of alfalfa plants inoculated with rhizobia

Grassland ecosystems resilience to drought: The role of surface water ponds

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