Multi-scene analysis of mangrove soil spectral response characteristics and inversion of soil organic carbon content based on measured full-spectrum hyperspectral data

doi:10.11947/j.AGCS.2026.20250393

Abstract

Abstract:

Mangroves, as an important component of the coastal ecosystem, the determination of soil organic carbon (SOC) content within them is of great significance for evaluating the carbon storage capacity of the coastal ecosystem. At present, research on mangrove soil is relatively scarce both at home and abroad. To address the issues of unclear spectral characteristics of mangrove soil and the difficulty in exploring SOC sensitive spectral subdomains, this study innovatively proposed the continuous wavelet spectral similarity angle (CSS) analysis method to systematically analyze the spectral response mechanism of mangrove soils. It also developed the soil sensitive spectral subdomain capture (CT-2DCOS) method to achieve accurate extraction of sensitive spectral subdomains for soil organic carbon (SOC) across multiple scenarios. Using in-situ full-band hyperspectral data (350~2500 nm) as the data source, this study combined the aforementioned methods to investigate the spectral reflection mechanisms of mangrove soils under three scenarios (different depths, tree species, and habitats), and further developed an adaptive ensemble learning (AEL) model to complete high-precision inversion of SOC content under these three scenarios. On this basis, it quantified the degree of influence of the three scenarios on SOC content via factor analysis and revealed the intrinsic correlations between mangrove SOC content and depth, tree species, and habitat by integrating significance tests. The results showed that: ① The soil spectra in the 400~800 nm band interval exhibited significant correlations with mangrove SOC content, among which the linear correlation between the spectra around 600 nm and SOC content was more prominent.②The sensitive spectral subdomains of soils at different depths were mainly concentrated in the 350~800 nm band, those of soils under different tree species were dominated by the 600~900 nm band, while those of soils in different habitats were distributed in two band intervals (350~900 nm and 1500~2200 nm).③The AEL model effectively achieved high-precision inversion of SOC content. Among the 42 inversion schemes, the coefficient of determination (R²) ranged from 0.46 to 0.98 within the 0~60 cm soil depth range, the 0~10 cm soil layer showed the optimal SOC inversion effect (R²=0.96), and this layer also had the highest SOC content, accounting for 25.05%; among the 5 mangrove tree species, the soil under Bruguiera sexangula forests exhibited the best SOC inversion effect (R²=0.97) and the highest SOC content, accounting for 27.16%; among the 3 habitats, the near-natural restoration area had the highest SOC inversion accuracy, with SOC content accounting for 45.24%. This study systematically clarifies the spectral response mechanism of mangrove soil under different scenarios, accurately captures its SOC diagnostic spectral bands, and achieves high-precision inversion of SOC content. Among them, the mining of the diagnostic spectral bands of mangrove soil can precisely match the bands of satellite images, providing scientific support for the hyperspectral remote sensing estimation of blue carbon in the coastal zone under large-scale and multi-scenario conditions.

Key words: mangroves, soil organic carbon, measured hyperspectral data, spectral characteristic analysis, depth and species, quantitative inversion

CLC Number:

P237

bolin FU, Keyue HUANG, Yanli YANG, Weiwei SUN, Zhaoyin WANG. Multi-scene analysis of mangrove soil spectral response characteristics and inversion of soil organic carbon content based on measured full-spectrum hyperspectral data[J]. Acta Geodaetica et Cartographica Sinica, 2026, 55(4): 604-617.

Figures/Tables 12

Fig. 1

Fig. 2

Fig. 3

Fig. 4

Fig. 5

Fig. 6

Fig. 7

Fig. 8

Tab. 1

Tab. 2

Tab. 3

Fig. 9

References 28

[1]	LOVELOCK C E, REEF R Variable impacts of climate change on blue carbon[J]. One Earth, 2020, 3(2): 195-211.
[2]	CEANTURI A, TUAHATU J W, LOKOLLO F F, et al. Mangrove ecosystems in southeast Asia region: mangrove extent, blue carbon potential and CO₂ emissions in 1996—2020[J]. Science of the Total Environment, 2024(915): 170052.
[3]	SHARMA S, SUWA R, RAY R, et al. Preface: blue carbon studies in Asia-Pacific regions: current status, gaps, and future perspectives[J]. Ecological Research, 2022, 37(1): 5-8.
[4]	HUANG X, WANG X, LI X, et al. Distribution pattern and influencing factors for soil organic carbon (SOC) in mangrove communities at Dongzhaigang, China[J]. Journal of Coastal Research, 2018, 34(2): 434-442.
[5]	BARRETO M B, LO MÓNACO S, DÍAZ R, et al. Soil organic carbon of mangrove forests (Rhizophora and Avicennia) of the Venezuelan Caribbean coast[J]. Organic Geochemistry, 2016, 100: 51-61.
[6]	马文婷, 高若. 蓝碳经济与海洋生态文明协同发展研究[J]. 江苏海洋大学学报(人文社会科学版), 2025, 23(3): 1-10.
	MA Wenting, GAO Ruo. Research on the coordinated development of blue carbon economy and marine ecological civilization[J]. Journal of Jiangsu Ocean University (Humanities and Social Sciences Edition), 2025, 23(3): 1-10.
[7]	尹成卓, 高小红, 宋奇, 等. 基于Sentinel-2影像的农田土壤有机碳含量估算——以湟水流域典型区域为例[J]. 激光与光电子学进展, 2025, 62(12): 294-305.
	YIN Chengzhuo, GAO Xiaohong, SONG, Qi, et al. Estimation of soil organic carbon content in farmland based on Sentinel-2 imagery: case study of a typical area in the Huangshui river basin[J]. Laser & Optoelectronics Progress, 2025, 62(12): 294-305.
[8]	曹霸, 凌成星. 基于GF-1遥感数据的若尔盖高寒沼泽湿地地上生物量与土壤有机碳密度估算[J]. 遥感技术与应用, 2021, 36(1): 229-236.
	CAO Ba, LING Chengxing, Estimation of aboveground biomass and soil organic carbon density of Zoige Alpine wetland based on GF-1 remote sensing data[J]. Remote Sensing Technology and Application, 2021, 36(1): 229-236.
[9]	HUANG C, GONG W, PANG Y. Remote sensing and forest carbon monitoring—a review of recent progress, challenges and opportunities[J]. Journal of Geodesy and Geoinformation Science, 2022, 5(2): 124.
[10]	周涛, 史培军, 罗巾英, 等. 基于遥感与碳循环过程模型估算土壤有机碳储量[J]. 遥感学报, 2007(1): 127-136.
	ZHOU Tao, SHI Peijun, LUO Jinying, et al. Estimation of soil organic carbon based on remote sensing and process model[J]. National Remote Sensing Bulletin, 2007(1): 127-136.
[11]	CASTALDI F, HALIL K M, WETTERLIND J, et al. Assessing the capability of Sentinel-2 time-series to estimate soil organic carbon and clay content at local scale in croplands[J]. ISPRS Journal of Photogrammetry and Remote Sensing, 2023, 199: 40-60.
[12]	ŽÍŽALA D, MINAŘÍK R, ZÁDOŘOVÁ T. Soil organic carbon mapping using multispectral remote sensing data: prediction ability of data with different spatial and spectral resolutions[J]. Remote Sensing, 2019, 11(24): 2947.
[13]	杨珺婷, 李晓松. 应用哨兵2号卫星遥感影像数据和机器学习算法对锡林郭勒草原土壤表层有机碳及全氮的估算[J]. 东北林业大学学报, 2022, 50(1): 64-71.
	YANG Junting, LI Xiaosong. Estimation of topsoil organic carbon and total nitrogen in Xilin Gol grassland using Sentinel-2 and machine learning[J]. Journal of Northeast Forestry University, 2022, 50(1): 64-71.
[14]	XU X, CHEN S, XU Z, et al. Exploring appropriate preprocessing techniques for hyperspectral soil organic matter content estimation in black soil area[J]. Remote Sensing, 2020, 12(22): 3765.
[15]	MENG X, BAO Y, LIU J, et al. Regional soil organic carbon prediction model based on a discrete wavelet analysis of hyperspectral satellite data[J]. International Journal of Applied Earth Observation and Geoinformation, 2020, 89: 102111.
[16]	XIAO B, LI S, DOU S, et al. Comparison of leaf Chlorophyll content retrieval performance of citrus using FOD and CWT methods with field-based full-spectrum hyperspectral reflectance data[J]. Computers and Electronics in Agriculture, 2024, 217: 108559.
[17]	HUANG X, WANG X, BAISHAN K, et al. Hyperspectral estimation of soil organic carbon content based on continuous wavelet transform and successive projection algorithm in arid area of Xinjiang, China[J]. Sustainability, 2023, 15(3): 2587.
[18]	XIA K, WU T, ZHANG S, et al. A new method for high-precision estimation of soil organic matter using two-dimensional correlation spectroscopy—to support collaborative use of global open soil spectral libraries[J]. Geoderma, 2024, 445: 116877.
[19]	LAUNER H F, TOMIMATSU Y. Rapid accurate determination of carbohydrates and other substances with dichromate heat-of-dilution method[J]. Analytical Chemistry, 1953, 25(11): 1767-1769.
[20]	SAVITZKY A, GOLAY M J E. Smoothing and differentiation of data by simplified least squares procedures[J]. Analytical Chemistry, 1964, 36(8): 1627-1639.
[21]	RIOUL O, DUHAMEL P. Fast algorithms for discrete and continuous wavelet transforms[J]. IEEE Transactions on Information Theory, 1992, 38(2): 569-586.
[22]	FU B, LIANG Y, LAO Z, et al. Quantifying scattering characteristics of mangrove species from Optuna-based optimal machine learning classification using multi-scale feature selection and SAR image time series[J]. International Journal of Applied Earth Observation and Geoinformation, 2023, 122: 103446.
[23]	SHEPHERD K D, FERGUSON R, HOOVER D, et al. A global soil spectral calibration library and estimation service[J]. Soil Security, 2022, 7: 100061.
[24]	WANG Z, CHEN S, LU R, et al. Non-linear memory-based learning for predicting soil properties using a regional vis-NIR spectral library[J]. Geoderma, 2024, 441: 116752.
[25]	ROWLEY M C, NICO P S, BONE S E, et al. Association between soil organic carbon and calcium in acidic grassland soils from Point Reyes National Seashore, CA[J]. Biogeochemistry, 2023, 165(1): 91-111.
[26]	WEI D L, BARET F, XING F G, et al. Relating soil surface moisture to reflectance[J]. Remote Sensing of Environment, 2002, 81(2): 238-246.
[27]	DING J, YANG A, WANG J, et al. Machine-learning-based quantitative estimation of soil organic carbon content by VIS/NIR spectroscopy[J]. PeerJ, 2018, 6: e5714.
[28]	DEMATTÊJ A M, TERRA F D S, QUARTAROLI C F. Spectral behavior of some modal soil profiles from S ã o Paulo State, Brazil[J]. Bragantia, 2012, 71(3): 413-423.

深度/cm	反演精度（R²）			最优反演基模型
深度/cm	Max	Mid	Min	Max	Mid	Min
0~10	0.65	0.95	0.96	AEL-PLS	AEL-XGBoost	AEL-RF
10~20	0.60	0.55	0.46	AEL-RF	AEL-PLS	AEL-PLS
20~30	0.75	0.77	0.76	AEL-PLS	AEL-PLS	AEL-PLS
30~40	0.88	0.82	0.50	AEL-RF	AEL-PLS	AEL-PLS
40~50	0.82	0.63	0.57	AEL-XGBoost	AEL-PLS	AEL-PLS
50~60	0.90	0.79	0.71	AEL-XGBoost	AEL-RF	AEL-XGBoost

树种	反演精度（R²）			最优反演基模型
树种	Max	Mid	Min	Max	Mid	Min
海莲	0.95	0.97	0.97	PLS	PLS	PLS
角果木	0.80	0.92	0.66	AEL-PLS	AEL-XGBoost	AEL-RF
红海榄	0.78	0.85	0.86	AEL-RF	AEL-PLS	AEL-PLS
正红树	0.98	0.96	0.99	PLS	PLS	PLS
无瓣海桑	0.96	0.95	0.94	PLS	PLS	PLS

生境	反演精度（R²）			最优反演基模型
生境	Max	Mid	Min	Max	Mid	Min
天然红树林区	0.70	0.61	0.62	AEL-LightGBM	AEL-PLS	AEL-RF
近自然恢复区	0.85	0.62	0.76	AEL-PLS	AEL-PLS	AEL-PLS
人工管理区	0.71	0.73	0.78	AEL-PLS	AEL-PLS	AEL-Catboost