Abstract
Forest degradation continues to increase globally, threatening biodiversity and the survival of species. In this context, identifying intact, old-growth forest stands is both urgent and vital to ensure their existence and multiple contributions to society. Despite the global ecological importance of the Valdivian temperate rainforests, they are threatened by forest degradation resulting from constant and intense human use in the region. Identification of remnant intact forests in this region is urgent to global forest protection efforts. In this paper, we analyzed whether forests-canopy alterations due to logging produce a distinctive canopy gap structure (e.g., a gap area and a fraction of canopy gaps in the forest) that can be used to remotely distinguish intact from altered forests. We tested this question by comparing the canopy gap structure of 12 old-growth temperate rainforests in south-central Chile (39–40° S), with different levels of canopy alterations due to logging. At each stand, we obtained aerial or satellite very high spatial-resolution images that were automatically segmented using the Mean-Shift segmentation algorithm. We validated the results obtained remotely with ground data on the canopy gap structure. We found that the variables, canopy gap fraction, gap area frequency distribution, and mean gap area could be measured remotely with a high level of accuracy. Intact forests have a distinct canopy gap structure in comparison to forests with canopy alterations due to logging. Our results provided a fast, low-cost, and reliable method to obtain canopy gap structure indicators for mapping and monitoring intact forests in the Valdivian ecoregion. The method provided valuable information for managers interested in maintaining and restoring old-growth forest structures in these southern-temperate rainforests.
Highlights
In recent decades, the concern about deforestation and forest degradation has increased due to the global decline in primary forests and the high percentage (82%) of degraded forest cover [1,2]
We found a strong relationship between the mean enhanced vegetation index (EVI) values obtained from the Landsat sensor and the gap area for intact forests, but this relationship was lost for altered forests (gap area = 443.329 × exp (EVI * −8.235955), r-Spearman = −0.74, p < 0.001, Figure 3)
We found that intact forests in the Valdivian ecoregion had gap areas
Summary
The concern about deforestation and forest degradation has increased due to the global decline in primary forests and the high percentage (82%) of degraded forest cover [1,2]. The loss of forest cover has accelerated since the 1990s [3,4]; remaining forests are more frequently converted to other land uses or are cut down and maintained in early successional stages [5]. This global trend endangers the remaining intact forests and the services that they provide to society, such as climate change mitigation and biodiversity [6]. We need to develop methods to detect alterations in the remaining intact forests to effectively map changes, prevent conversion, and facilitate conservation efforts
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