Soil organic matter in natural and rehabilitated mangroves: Implications for environmental restoration and climate resilience
Issued Date
2025-01-01
Resource Type
eISSN
22998993
Scopus ID
2-s2.0-85210768664
Journal Title
Journal of Ecological Engineering
Volume
26
Issue
1
Start Page
153
End Page
162
Rights Holder(s)
SCOPUS
Bibliographic Citation
Journal of Ecological Engineering Vol.26 No.1 (2025) , 153-162
Suggested Citation
Dharmayasa I.G.N.P., Sugiana I.P., Prapaspongsa T. Soil organic matter in natural and rehabilitated mangroves: Implications for environmental restoration and climate resilience. Journal of Ecological Engineering Vol.26 No.1 (2025) , 153-162. 162. doi:10.12911/22998993/195515 Retrieved from: https://repository.li.mahidol.ac.th/handle/20.500.14594/103011
Title
Soil organic matter in natural and rehabilitated mangroves: Implications for environmental restoration and climate resilience
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Author's Affiliation
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Abstract
Mangrove ecosystems contribute significantly to coastal stability, providing essential services like carbon sequestration and storm protection. The rehabilitation of mangroves in Indonesia is essential to restore ecological functions disrupted by coastal development. This study aims to compare the ratios of organic matter – carbon (C), nitrogen (N), and phosphorus (P) – in the soils of natural and rehabilitated mangroves in Benoa Bay, Bali. The research was conducted across eight plots in natural and rehabilitated mangrove forests, with soil samples collected using an auger at depths ranging from 0 to 100 cm. Organic matter analysis was performed using the loss on ignition (LOI) method for soil organic carbon (SOC), the FIA method for total nitrogen (TKN), and the colorimetric persulfate digestion method for total phosphorus (TP). The results indicate that rehabilitated mangroves have lower total organic carbon (1.1±0.5%) and higher total nitrogen content (0.07±0.02%) compared to natural mangroves. Total phosphorus content is also lower in rehabilitated areas (0.010±0.003%), possibly due to increased clay content that binds phosphorus in the soil. Several parameters are closely related to organic matter, including bulk density, soil type, oxidation-reduction potential (ORP), pH, and dissolved oxygen (DO) in pore water, as well as the structure of mangrove stands, such as tree and seedling density, stem diameter, canopy cover, and mangrove health condition. Variations in organic matter content and C:N ratios suggest that rehabilitated mangrove ecosystems have not yet reached the stability of natural ecosystems. This is reflected in altered biogeochemical cycles and nutrient availability. Therefore, ongoing efforts are needed to ensure a more comprehensive recovery in the mangrove rehabilitation process. These findings emphasize the need for targeted interventions in mangrove rehabilitation to restore nutrient balance, optimize carbon storage, and enhance resilience to climate change in tropical coastal ecosystems.