What does this research mean for the field?

Hyperspectral reflectance data, particularly in the near-infrared and red-edge regions, can effectively discriminate between wetland plant species and assess their physiological stress and productivity in complex coastal environments. Novelty: ClaimNovelty.INCREMENTAL. Consensus alignment: ConsensusAlignment.NEUTRAL.

What question did this study set out to answer?

This study aims to integrate floristic surveys and hyperspectral measurements to evaluate wetland vegetation and its ecological adaptations.

June 1, 2026Open Access

Integrated floristic, environmental, and hyperspectral characterization of wetland vegetation in lake Manzala: implications for ecosystem functioning

Puntos clave

This study aims to integrate floristic surveys and hyperspectral measurements to evaluate wetland vegetation and its ecological adaptations.
Conducted floristic analysis of 55 vascular plant species in various wetland habitats.
Utilized hyperspectral reflectance data (350–2,500 nm) for assessing vegetation spectral behavior.
Performed one-way ANOVA to analyze interspecific spectral differences.
Marked variation in vegetation composition among habitats with emergent species along shores and hydrophytes in open water.
Strong species discrimination was observed in near-infrared and red-edge regions of the spectrum.
Vegetation indices indicated high productivity in certain species, while halophytic species showed signs of stress.

Resumen

Introduction Lake Manzala, the largest coastal lake in the Northeastern Nile Delta of Egypt, represents a highly disturbed wetland system shaped by strong environmental gradients and persistent anthropogenic pressure. This study integrates floristic surveys with field-based hyperspectral measurements to assess vegetation structure, ecological adaptation, and species-level spectral discrimination across lake shore, islet, and open-water habitats. Methods Floristic analysis of georeferenced stands identified 55 vascular plant species belonging to 26 families, dominated by perennial taxa and widely distributed chorotypes. Hyperspectral reflectance data (350–2,500 nm) were collected using an ASD FieldSpec spectroradiometer to evaluate vegetation spectral behavior and physiological responses across different wetland habitats. Results Vegetation composition varied markedly among habitats, with emergent and terrestrial species prevailing along lake shores, while floating and submerged hydrophytes dominated open-water zones. Hyperspectral measurements revealed strong species discrimination, particularly in the near-infrared (NIR) and red-edge regions. These wavelengths effectively separated emergent macrophytes (Phragmites australis and Typha domingensis) from submerged species (Ceratophyllum demersum and Potamogeton pectinatus), while shortwave infrared (SWIR) bands captured variations in leaf water content and biochemical composition. Vegetation indices indicated high productivity in Cyperus alopecuroides, Echinochloa stagnina, and P. pectinatus, whereas halophytic and stress-tolerant species exhibited lower NDVI and elevated stress and senescence indicators. One-way ANOVA confirmed significant interspecific spectral differences ( p 0.05). Discussion By integrating hyperspectral sensing with plant functional ecology, this study provides a robust, non-destructive approach for vegetation monitoring, species-level discrimination, and ecological assessment in complex wetland environments.

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