Surface albedo as a proxy for land-cover clearing in seasonally dry forests: Evidence from the Brazilian Caatinga

Ongoing increase in human and climate pressures, in addition to the lack of monitoring initiatives, makes the Caatinga one of the most vulnerable forests in the world. The Caatinga is located in the semi-arid region of Brazil and its vegetation phenology is highly dependent on precipitation, which h...

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Bibliographic Details
Published in:Remote sensing of environment 2020-03, Vol.238, p.111250, Article 111250
Main Authors: Cunha, John, Nóbrega, Rodolfo L.B., Rufino, Iana, Erasmi, Stefan, Galvão, Carlos, Valente, Fernanda
Format: Article
Language:English
Subjects:
Albedo
Arid regions
Arid zones
Breakpoints
Change detection
Clearing
Climate
Climate and vegetation
Climate change
Climate effects
Dry forests
Forests
Human influences
Human performance
Land cover
Land use
Land-cover change
Landsat
Landsat satellites
Monitoring
Normalized difference vegetative index
Remote sensing
Satellite imagery
Semi arid areas
Semi-arid climate
Semiarid lands
Semiarid zones
Short wave radiation
Temporal variability
Time series
Trend analysis
Vegetation
Vegetation index
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Summary:Ongoing increase in human and climate pressures, in addition to the lack of monitoring initiatives, makes the Caatinga one of the most vulnerable forests in the world. The Caatinga is located in the semi-arid region of Brazil and its vegetation phenology is highly dependent on precipitation, which has a high spatial and temporal variability. Under these circumstances, satellite image-based methods are valued due to their ability to uncover human-induced changes from climate effects on land cover. In this study, a time series stack of 670 Landsat images over a period of 31 years (1985–2015) was used to investigate spatial and temporal patterns of land-cover clearing (LCC) due to vegetation removal in an area of the Caatinga. We compared the LCC detection accuracy of three spectral indices, i.e., the surface albedo (SA), the Enhanced Vegetation Index (EVI) and the Normalized Difference Vegetation Index (NDVI). We applied a residual trend analysis (TSS-RESTREND) to attenuate seasonal climate effects on the vegetation time series signal and to detect only significant structural changes (breakpoints) from monthly Landsat time series. Our results show that SA was able to identify the general occurrence of LCC and the year that it occurred with a higher accuracy (89 and 62%, respectively) compared to EVI (44 and 22%) and NDVI (46 and 22%). The overall outcome of the study shows the benefits of using Landsat time series and a spectral index that incorporates the short-wave infrared range, such as the SA, compared to visible and near-infrared vegetation indices for monitoring LCC in seasonally dry forests such as the Caatinga. [Display omitted] •TSS-RESTREND is an efficient approach for identifying land-cover clearing in the Caatinga•Surface albedo effectively identified land-cover clearing in this seasonally dry forest•EVI and NDVI exhibited low performance in identifying land-cover clearing
ISSN:0034-4257
1879-0704
DOI:10.1016/j.rse.2019.111250