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April 1, 2026Open Access

Spatial Assessment of Soil Properties and Soil Quality Dynamics (SFI and SQI) on Hainan Island Using Field Observations and Remote Sensing Data

Key Points

This research aims to evaluate soil properties and quality dynamics on Hainan Island using field and remote sensing data.
Conducted field surveys at 152 sampling sites in 2024, collecting three topsoil samples each.
Analyzed multi-temporal remote sensing data from 2021 to 2024, including SRSI, SI, NDVI, and LULC.
Calculated soil fertility and quality indices based on nitrogen, phosphorus, potassium, soil pH, SOM, and chromium.
Applied the Inverse Distance Weighting method to create spatial distribution maps.
Soils were mainly acidic (pH < 6.0) with low electrical conductivity in inland areas.
Higher salinity levels were reported in southern and eastern coastal zones, indicating seawater intrusion.
Nutrient concentrations varied widely, with nitrogen between 60.1 and 150 mg kg−1, phosphorus from 4 to 332 mg kg−1, and potassium from 50.1 to 100 mg kg−1.
High NDVI values suggested dense vegetation in agricultural areas.
Significant positive correlations were found between soil electrical conductivity and remote sensing indices.

Abstract

Soil salinity and nutrient availability are major constraints affecting crop productivity, soil quality, and agroecosystem sustainability, particularly in coastal regions vulnerable to seawater intrusion. This study provides a comprehensive spatial and temporal assessment of soil properties and quality dynamics on Hainan Island by integrating field observations and multi-temporal remote sensing (RS) datasets. In 2024, a total of 152 sampling sites were surveyed, with three topsoil soil samples collected at each location. Multi-year RS data (2024–2021), including soil salinity reflectance indices (SRSI and SI), the Normalized Difference Vegetation Index (NDVI), and land use and land cover (LULC), were analyzed to evaluate temporal and spatial variability. The soil fertility index was calculated using alkali-hydrolyzed nitrogen (AN), available phosphorus (AP), available potassium (AK), soil pH, and soil organic matter (SOM). The soil quality index was calculated using the same parameters with the addition of chromium (Cr) to account for potential heavy metal contamination. Furthermore, in this study the Inverse Distance Weighting (IDW) method was used for spatial distribution maps of soil properties and other indices. The results indicated that soils were predominantly acidic (pH < 6.0) with generally low electrical conductivity (0.01–0.53 mS cm−1) across inland areas, whereas higher salinity levels (2.28–5.31 mS cm−1) were observed in southern and eastern coastal zones, suggesting potential seawater intrusion. Nutrient concentrations ranged from 60.1 to 150 mg kg−1 (AN), 4 to 332 mg kg−1 (AP), and 50.1 to 100 mg kg−1 (AK). NDVI values (0.70–0.94) indicated high vegetation density over most agricultural landscapes. Significant positive correlations were observed between soil EC and the SRSI (r = 0.781) and SI (r = 0.663; p < 0.01), demonstrating the reliability of RS-derived indices for salinity assessment. The integrated indicator-based framework developed in this study provides a scientific basis for precision agriculture, soil health monitoring, and sustainable land management in coastal agroecosystems.

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Cite This Study

Zeng et al. (Mon,) studied this question.

synapsesocial.com/papers/69ccb5f716edfba7beb87afb https://doi.org/https://doi.org/10.3390/agriculture16070762

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