Nutrient return through decomposing Coriaria nepalensis litter in degraded hills of Kumaun Himalaya, India

Awasthi, Pankaj; Bargali, Kiran; Bargali, Surendra Singh; Khatri, Kavita

doi:10.3389/ffgc.2022.1008939

Cited by 12 publications

(4 citation statements)

References 60 publications

(55 reference statements)

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“…The highest sand percentage has been observed in LWA, silt in CP, and clay in PCM. When we look at bulk density, it was seen higher in OL with 2.01 g/cm 3 when compared to CP with 1.65 g/cm 3 , indicating that it is more than 10% higher in open lands due to cropping systems. A significant variation has been observed in the WHC parameter, where PCM was identified at 51.2% with the highest and CP with the lowest at 33.24%.…”

Section: Physicochemical Characteristicsmentioning

confidence: 89%

Impact of Cropping Systems on Macronutrient Distribution and Microbial Biomass in Drought Affected Soils

Jayasudha,

Reddy,

Bargali

2024

Preprint

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Abstract. The interplay between soil nutrients, water activity, and microbial biomass is pivotal for plant growth as well as for soil health. While surface microflora typically promotes mineralization and nutrient deposits, the impact of drought on soil microbial biomass and nutrient utilization remains underexplored. In this study, we assessed various land types—open lands (OL), annual crops with single species (ACS), perennial crops with multiple species (PCM), less water available lands (LWA), and soil near ponds (CP)—to elucidate the distribution of macronutrients and microbial biomass. Soil samples were collected from different land types, air-dried, and subjected to physical, chemical, and biological analyses. Standardized protocols, including gravimetric and titration analyses, were employed for physical and chemical assessments, while microbial biomass was evaluated using fumigation. Statistical analyses, including ANOVA and Pearson Coefficient, were employed to discern patterns across seasons, soil depths, and microbial biomass. Microbial biomass carbon (Cmic) ranged from 134.2±1.2 μg/g to 286.6±1.33 μg/g, while nitrogen (Nmic) and phosphorus (Pmic) varied from 11.3±1.3 μg/g to 69.5±0.98 μg/g and 07.6±1.5 μg/g to 77.5±0.6 μg/g, respectively, across all seasons. Carbon stock in the upper soil surface positively influenced nitrogen and phosphorus retention. Notably, PCM exhibited superior Cmic, Nmic, Pmic, and water-holding capacity compared to OL, LWA, and ACS. Our findings underscore the significance of multiple cropping systems, particularly PCM, in enhancing microbial biomass and nutrient levels in drought-affected regions. The observed improvements in soil moisture, nitrogen, phosphorous, and potassium levels suggest that diverse cropping systems can effectively enrich soil nutrients and biomass content in drought stress. In conclusion, our study highlights the potential of perennial crops with multiple species in mitigating the impact of drought on soil microbial biomass and macronutrient distribution. These findings contribute to a deeper understanding of sustainable agricultural practices in drought-prone regions and emphasize the importance of implementing diverse cropping systems to enhance soil health and resilience.

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Section: Physicochemical Characteristicsmentioning

confidence: 89%

Impact of Cropping Systems on Macronutrient Distribution and Microbial Biomass in Drought Affected Soils

Jayasudha,

Reddy,

Bargali

2024

Preprint

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“…Herbaceous plants may also influence SOC accumulation through the three pathways described above ( Yang et al., 2019b ). In summary, vegetation plays a significant role in the formation of soil organic matter and influences fundamental soil forming processes such as aggregation or podzolization ( Awasthi et al., 2022b ; Awasthi et al., 2022c ). Notably, soil aggregates are known to be the main sites of SOC fixation ( Shankar and Suresha, 2006 ; Bai et al., 2020 ).…”

Section: Discussionmentioning

confidence: 99%

Plant diversity drives soil carbon sequestration: evidence from 150 years of vegetation restoration in the temperate zone

Tian

Zhang

et al. 2023

Front. Plant Sci.

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Large-scale afforestation is considered a natural way to address climate challenges (e.g., the greenhouse effect). However, there is a paucity of evidence linking plant diversity to soil carbon sequestration pathways during long-term natural restoration of temperate vegetation. In particular, the carbon sequestration mechanisms and functions of woody plants require further study. Therefore, we conducted a comparative study of plant diversity and soil carbon sequestration characteristics during 150 years of natural vegetation restoration in the temperate zone to provide a comprehensive assessment of the effects of long-term natural vegetation restoration processes on soil organic carbon stocks. The results suggested positive effects of woody plant diversity on carbon sequestration. In addition, fine root biomass and deadfall accumulation were significantly positively correlated with soil organic carbon stocks, and carbon was stored in large grain size aggregates (1–5 mm). Meanwhile, the diversity of Fabaceae and Rosaceae was observed to be important for soil organic carbon accumulation, and the carbon sequestration function of shrubs should not be neglected during vegetation restoration. Finally, we identified three plants that showed high potential for carbon sequestration: Lespedeza bicolor, Sophora davidii, and Cotoneaster multiflorus, which should be considered for inclusion in the construction of local artificial vegetation. Among them, L. bicolor is probably the best choice.

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“…The ecosystem functions and services like primary productivity, nutrient cycling, and carbon fixation can be altered through potential forest losses (Ziegler et al, 2009;Gibson et al, 2011;Domec et al, 2015;van Straaten et al, 2015;Singh et al, 2021). The heterogeneous association of soil organic matter, characterizing the end products of several stabilizing processes, is responsible for nutrient cycling and the flow of energy (Bargali, 1994(Bargali, , 1996Awasthi et al, 2022c). The change in plant species diversity demonstrates how adaptable a forest ecosystem is to climate change.…”

Section: Introductionmentioning

confidence: 99%

Litter dynamics of forest ecosystem in an urban and pristine area of West Bengal, India

Banerjee,

Gangopadhyay,

Batabyal

et al. 2023

JEB

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Aim: A comparative assessment of forest litterfall dynamics was carried out between the Garadaha forest (GF or urban) and the Pratappur forest (PF or pristine), located in Burdwan districts of West Bengal, and the litterfall components were correlated with the environmental factors that govern the dynamics. Methodology: Nets of dimension 1m × 1m were placed below the tress of both forests and litter was collected at regular intervals per month and brought to the laboratory for separation into the categories like leaf litter, woody litter (bark), miscellaneous (mixed) and twig. Two types of litterfall such as specific litterfall and standing litterfall were calculated. Environmental factors such as maximum and minimum temperature, rainfall, relative humidity, wind speed, solar irradiance, and photosynthetically active radiation (PAR) were studied simultaneously followed by correlation and Principal Component Analysis. Results: Pre-monsoon showed the highest total litterfall (specific litterfall and standing litterfall) in both types of forests. The decomposition quotient was higher in the pristine forest than in the urban forest. The correlation between litterfall components and environmental factors showed that solar irradiance was positively correlated with litterfall dynamics. Interpretation: The work emphasizes the forest management of urban areas impacted by industrialization and urbanization. The anthropogenic causes influence the plant growth and litterfall pattern thereby affecting the decomposition process and soil health. The selection of proper tree species should be given priority for social forestry in industrialized zones of India. Key words: Litter decomposition, Seasonal pattern, Solar irradiance, Standing litter, Temperature

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Nutrient return through decomposing Coriaria nepalensis litter in degraded hills of Kumaun Himalaya, India

Cited by 12 publications

References 60 publications

Impact of Cropping Systems on Macronutrient Distribution and Microbial Biomass in Drought Affected Soils

Impact of Cropping Systems on Macronutrient Distribution and Microbial Biomass in Drought Affected Soils

Plant diversity drives soil carbon sequestration: evidence from 150 years of vegetation restoration in the temperate zone

Litter dynamics of forest ecosystem in an urban and pristine area of West Bengal, India

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