Cork and Compost as Mitigators of Soil Compaction from Trampling in Urban Green Areas: Effects on Plant Growth and Soil Functionality

Cork and Compost as Mitigators of Soil Compaction from Trampling in Urban Green Areas: Effects on Plant Growth and Soil Functionality

Compacted soils in urban areas suffer from reduced porosity, impairing plant growth, water infiltration, and gas exchange, thus exacerbating other potential environmental issues. Amending soil with organic matter can reduce bulk density and increase permeability, thereby enhancing soil fertility and...

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Main Authors: Bianca Rompato, Lucia Mondanelli, Ermes Lo Piccolo, Claudia Cocozza, Giovanni Mastrolonardo, Laura Giagnoni, Gregorio Fantoni, Alessandro Bizzarri, Barbara Mariotti, Leonardo Verdi, Alberto Maltoni, Francesco Ferrini, Giacomo Certini
Format: Article
Language:English
Published: MDPI AG 2024-12-01
Series:Urban Science
Subjects:
maximum daily trunk shrinkage
photosynthesis
plant physiology
soil enzymatic activity
soil health
soil respiration
Online Access:https://www.mdpi.com/2413-8851/9/1/5
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Summary:Compacted soils in urban areas suffer from reduced porosity, impairing plant growth, water infiltration, and gas exchange, thus exacerbating other potential environmental issues. Amending soil with organic matter can reduce bulk density and increase permeability, thereby enhancing soil fertility and functionality. This study evaluated the effects of two organic soil amendments (i.e., chipped cork and municipal waste compost) on soil functionality and the physiology of <i>Quercus ilex</i> trees, following a soil compaction treatment. Five soil treatments were compared: control (no compaction and amendments), soil compaction without amendments, and compaction with amendments including cork, compost, or a combination of both. Soil and plant physiological responses were analyzed during the summer months, focusing on soil gas exchange, temperature, moisture, microbial respiration, enzymatic activity, leaf gas exchange, leaf chlorophyll fluorescence, chlorophyll content, and maximum daily trunk shrinkage. The results showed that amended soils exhibited increased soil gas exchanges, lower temperatures, and higher microbial activity than non-amended compacted soils, thereby reducing the detrimental effects of soil compaction on plant physiology. These findings suggested that incorporating organic amendments into urban soils, especially those subjected to frequent trampling, could make them more resistant/resilient to compaction, supporting healthier green spaces and more sustainable urban ecosystems.
ISSN:2413-8851

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