Forest cover change in China from 2000 to 2016

Accurate remote sensing of mountainous forest cover change is important for myriad social and ecological reasons, but is challenged by topographic and illumination conditions that can affect detection of forests. Several topographic illumination correction (TIC) approaches have been developed to mitigate these effects, but existing research has focused mostly on whether TIC improves forest cover classification accuracy and has usually found only marginal gains. However, the beneficial effects of TIC may go well beyond accuracy since TIC promises to improve detection of low illuminated forest cover and thereby normalize measurements of the amount, geographic distribution, and rate of forest cover change regardless of illumination. To assess the effects of TIC on the extent and geographic distribution of forest cover change, in addition to classification accuracy, we mapped forest cover across mountainous Nepal using a 25-year (1992–2016) gap-filled Landsat time series in two ways—with and without TIC (i.e., nonTIC)—and classified annual forest cover using a Random Forest classifier. We found that TIC modestly increased classifier accuracy and produced more conservative estimates of net forest cover change across Nepal (−5.2% from 1992–2016) TIC. TIC also resulted in a more even distribution of forest cover gain across Nepal with 3–5% more net gain and 4–6% more regenerated forest in the least illuminated regions. These results show that TIC helped to normalize forest cover change across varying illumination conditions with particular benefits for detecting mountainous forest cover gain. We encourage the use of TIC for satellite remote sensing detection of long-term mountainous forest cover change.

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Interannual evolution of hydrosedimentary connectivity induced by forest cover change in a snow‐dominated mountainous catchment

Land Degradation and Development ◽

10.1002/ldr.3902 ◽

2021 ◽

Author(s):

Timothée Jautzy ◽

Maxime Maltais ◽

Thomas Buffin‐Bélanger

Keyword(s):

Forest Cover ◽

Forest Cover Change ◽

Mountainous Catchment

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Synthesizing published knowledge of boreal forest cover change for large-scale landscape dynamics modelling

The Forestry Chronicle ◽

10.5558/tfc79132-1 ◽

2003 ◽

Vol 79 (1) ◽

pp. 132-146 ◽

Cited By ~ 3

Author(s):

Dennis Yemshanov ◽

Ajith H Perera

Keyword(s):

Boreal Forest ◽

Large Scale ◽

Forest Canopy ◽

Forest Cover ◽

Forest Succession ◽

Simulation Models ◽

Limiting Factors ◽

Sources Of Information ◽

Forest Cover Change ◽

Discrete State

We reviewed the published knowledge on forest succession in the North American boreal biome for its applicability in modelling forest cover change over large extents. At broader scales, forest succession can be viewed as forest cover change over time. Quantitative case studies of forest succession in peer-reviewed literature are reliable sources of information about changes in forest canopy composition. We reviewed the following aspects of forest succession in literature: disturbances; pathways of post-disturbance forest cover change; timing of successional steps; probabilities of post-disturbance forest cover change, and effects of geographic location and ecological site conditions on forest cover change. The results from studies in the literature, which were mostly based on sample plot observations, appeared to be sufficient to describe boreal forest cover change as a generalized discrete-state transition process, with the discrete states denoted by tree species dominance. In this paper, we outline an approach for incorporating published knowledge on forest succession into stochastic simulation models of boreal forest cover change in a standardized manner. We found that the lack of details in the literature on long-term forest succession, particularly on the influence of pre-disturbance forest cover composition, may be limiting factors in parameterizing simulation models. We suggest that the simulation models based on published information can provide a good foundation as null models, which can be further calibrated as detailed quantitative information on forest cover change becomes available. Key words: probabilistic model, transition matrix, boreal biome, landscape ecology

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Amazon forest cover change mapping based on semantic segmentation by U-Nets

Ecological Informatics ◽

10.1016/j.ecoinf.2021.101279 ◽

2021 ◽

Vol 62 ◽

pp. 101279

Author(s):

L. Bragagnolo ◽

R.V. da Silva ◽

J.M.V. Grzybowski

Keyword(s):

Forest Cover ◽

Semantic Segmentation ◽

Amazon Forest ◽

Forest Cover Change

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Effectiveness of Protected Areas in the Pan-Tropics and International Aid for Conservation

Geomatics ◽

10.3390/geomatics1030019 ◽

2021 ◽

Vol 1 (3) ◽

pp. 335-346

Author(s):

Do-Hyung Kim ◽

Anupam Anand

Keyword(s):

Protected Areas ◽

Forest Conservation ◽

Forest Cover ◽

International Aid ◽

Asian Countries ◽

Forest Cover Change ◽

Average Effect ◽

Tropical Countries ◽

Conservation Policies ◽

The Tropics

Evaluation of the effectiveness of protected areas is critical for forest conservation policies and priorities. We used 30 m resolution forest cover change data from 1990 to 2010 for ~4000 protected areas to evaluate their effectiveness. Our results show that protected areas in the tropics avoided 83,500 ± 21,200 km2 of deforestation during the 2000s. Brazil’s protected areas have the largest amount of avoided deforestation at 50,000 km2. We also show the amount of international aid received by tropical countries compared to the effectiveness of protected areas. Thirty-four tropical countries received USD 42 billion during the 1990s and USD 62 billion during the 2000s in international aid for biodiversity conservation. The effectiveness of international aid was highest in Latin America, with 4.3 m2/USD, led by Brazil, while tropical Asian countries showed the lowest average effect of international aid, reaching only 0.17 m2/USD.

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Forest-Cover Change and Participatory Forest Management of the Lembus Forest, Kenya

Environments ◽

10.3390/environments3030020 ◽

2016 ◽

Vol 3 (4) ◽

pp. 20

Author(s):

Donald Kimutai ◽

Teiji Watanabe

Keyword(s):

Forest Management ◽

Forest Cover ◽

Forest Cover Change ◽

Participatory Forest Management

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Distance metric-based forest cover change detection using MODIS time series

International Journal of Applied Earth Observation and Geoinformation ◽

10.1016/j.jag.2014.01.004 ◽

2014 ◽

Vol 29 ◽

pp. 78-92 ◽

Cited By ~ 19

Author(s):

Xiaoman Huang ◽

Mark A. Friedl

Keyword(s):

Time Series ◽

Change Detection ◽

Forest Cover ◽

Distance Metric ◽

Forest Cover Change

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Qualifying Land Use and Land Cover Dynamics and Their Impacts on Ecosystem Service in Central Himalaya Transboundary Landscape Based on Google Earth Engine

Land ◽

10.3390/land10020173 ◽

2021 ◽

Vol 10 (2) ◽

pp. 173

Author(s):

Changjun Gu ◽

Yili Zhang ◽

Linshan Liu ◽

Lanhui Li ◽

Shicheng Li ◽

...

Keyword(s):

Land Use ◽

Ecosystem Services ◽

Land Cover ◽

Ecosystem Service ◽

Forest Cover ◽

Google Earth ◽

Forest Cover Change ◽

Sacred Landscape ◽

Lulc Changes ◽

Google Earth Engine

Land use and land cover (LULC) changes are regarded as one of the key drivers of ecosystem services degradation, especially in mountain regions where they may provide various ecosystem services to local livelihoods and surrounding areas. Additionally, ecosystems and habitats extend across political boundaries, causing more difficulties for ecosystem conservation. LULC in the Kailash Sacred Landscape (KSL) has undergone obvious changes over the past four decades; however, the spatiotemporal changes of the LULC across the whole of the KSL are still unclear, as well as the effects of LULC changes on ecosystem service values (ESVs). Thus, in this study we analyzed LULC changes across the whole of the KSL between 2000 and 2015 using Google Earth Engine (GEE) and quantified their impacts on ESVs. The greatest loss in LULC was found in forest cover, which decreased from 5443.20 km2 in 2000 to 5003.37 km2 in 2015 and which mainly occurred in KSL-Nepal. Meanwhile, the largest growth was observed in grassland (increased by 548.46 km2), followed by cropland (increased by 346.90 km2), both of which mainly occurred in KSL-Nepal. Further analysis showed that the expansions of cropland were the major drivers of the forest cover change in the KSL. Furthermore, the conversion of cropland to shrub land indicated that farmland abandonment existed in the KSL during the study period. The observed forest degradation directly influenced the ESV changes in the KSL. The total ESVs in the KSL decreased from 36.53 × 108 USD y−1 in 2000 to 35.35 × 108 USD y−1 in 2015. Meanwhile, the ESVs of the forestry areas decreased by 1.34 × 108 USD y−1. This shows that the decrease of ESVs in forestry was the primary cause to the loss of total ESVs and also of the high elasticity. Our findings show that even small changes to the LULC, especially in forestry areas, are noteworthy as they could induce a strong ESV response.

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