Abstract
Given the scale and rate of mangrove loss globally, it is increasingly important to map and monitor mangrove forest health in a timely fashion. This study aims to identify the conditions of mangroves in a coastal lagoon south of the city of Mazatlán, Mexico, using proximal hyperspectral remote sensing techniques. The dominant mangrove species in this area includes the red (Rhizophora mangle), the black (Avicennia germinans) and the white (Laguncularia racemosa) mangrove. Moreover, large patches of poor condition black and red mangrove and healthy dwarf black mangrove are commonly found. Mangrove leaves were collected from this forest representing all of the aforementioned species and conditions. The leaves were then transported to a laboratory for spectral measurements using an ASD FieldSpec® 3 JR spectroradiometer (Analytical Spectral Devices, Inc., USA). R2 plot, principal components analysis and stepwise discriminant analyses were then used to select wavebands deemed most appropriate for further mangrove classification. Specifically, the wavebands at 520, 560, 650, 710, 760, 2100 and 2230 nm were selected, which correspond to chlorophyll absorption, red edge, starch, cellulose, nitrogen and protein regions of the spectrum. The classification and validation indicate that these wavebands are capable of identifying mangrove species and mangrove conditions common to this degraded forest with an overall accuracy and Khat coefficient higher than 90% and 0.9, respectively. Although lower in accuracy, the classifications of the stressed (poor condition and dwarf) mangroves were found to be satisfactory with accuracies higher than 80%. The results of this study indicate that it could be possible to apply laboratory hyperspectral data for classifying mangroves, not only at the species level, but also according to their health conditions.
Highlights
Mangrove forests represent wetlands of local, regional and even global importance
This study aimed to examine the separation of mangrove species with various health conditions using in situ hyperspectral data collected from mangrove leaves
The results of this study indicate that it is possible to select bands using a few statistical methods and apply them, using a discriminant analysis based on quadratic discriminant functions, to classify mangroves with varying conditions
Summary
Mangrove forests represent wetlands of local, regional and even global importance. Mangroves provide a variety of renewable resources and are critical to the health of fisheries. And globally, mangrove forests are considered key carbon sinks and play an important role as an indispensable habitat for a variety of aquatic and terrestrial organisms. Mangrove forests have experienced a worldwide degradation due to several reasons, such as pollution, hydrological changes, aquaculture, recreational activities, climate changes, etc. Degraded mangrove forests generally have lower productivity and, provide less ecosystem goods and services than their healthier counterparts. It is crucial that resource managers be able to map and monitor mangrove forests at increasing levels of detail, including species distribution and health condition
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