Deforestation of montane cloud forest in the Central Highlands of Guatemala: contributing factors and implications for sustainability in Q’eqchi’ communities

Pope, I.; Bowen, Dawn S.; Harbor, Jonathan M.; Shao, Gang; Zanotti, Laura; Burniske, Gary R.

doi:10.1080/13504509.2014.998738

Cited by 21 publications

(15 citation statements)

References 37 publications

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“…Using a transdisciplinary framework that synthesized remote sensing and GIS analysis of landcover change, focus group dialogues and surveys, Pope et al, (2015) analyzed cloud forests in the Central Highlands of Guatemala. The study, found that expansion of subsistence agriculture is a key proximate cause of cloud forest removal, followed by extraction of fuelwood and larger-scale logging operations.…”

Section: Remote Sensing Gis and Tropical Forest Managementmentioning

confidence: 99%

Perspectives of Remote Sensing and GIS Applications in Tropical Forest Management

Beckline¹,

Sun²,

Baninla³

et al. 2017

AJAF

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Abstract:Tropical forest management requires could be improved through the use of current technologies including remote sensing and Geographic Information System (GIS). In this paper, we characterize and evaluate forest management patterns and relate this to modern technologies such as geographical information systems and remote sensing. We further examine the application of these modern technologies in tropical forestry and conservation. To achieve this, we carried out a comprehensive survey of published scientific literature obtained through Web of Science, Mendeley, Researchgate and Google Scholar. We observed that, the relationships between forestry management, modern technologies have shifted over time. These have depended on how management activities such as planting and harvesting, interact with other drivers and disturbances (fire, pests and diseases) to influence the adaptive capacity of forests. Forest management and new technologies are interrelated because the technologies support management actions; hence contribute to global forest resources management and conservation.

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Section: Remote Sensing Gis and Tropical Forest Managementmentioning

confidence: 99%

Perspectives of Remote Sensing and GIS Applications in Tropical Forest Management

Beckline¹,

Sun²,

Baninla³

et al. 2017

AJAF

View full text Add to dashboard Cite

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“…Along with the development of sensor and computation technologies, remote sensing applications in forestry have evolved from conventional aerial photography-based forest inventories (Lyons 1966) to satellite imagery-based forest resource monitoring (Asner et al 2005;Tang et al 2010;Pope et al 2015), from multispectral data-based forest cover mapping (Zhu and Evans 1994;Shao et al 1996) to hyperspectral data-based biophysical forest estimations (Martin and Aber 1997;Treitz and Howarth 1999), and from passive remote sensing-based forest leaf area index measurements (Turner et al 1999;Thakur et al 2014) to active remote sensing-based forest structure characterizations (Dubayah and Drake 2000;Lefsky et al 2002). Through the integration of multiple data sources, it is possible to improve estimations of forest volume and biomass (Lu 2006;Koch 2010).…”

Section: Introductionmentioning

confidence: 99%

Drone remote sensing for forestry research and practices

2015

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Drones of various shapes, sizes, and functionalities have emerged over the past few decades, and their civilian applications are becoming increasingly appealing. Flexible, low-cost, and high-resolution remote sensing systems that use drones as platforms are important for filling data gaps and supplementing the capabilities of crewed/manned aircraft and satellite remote sensing systems. Here, we refer to this growing remote sensing initiative as drone remote sensing and explain its unique advantages in forestry research and practices. Furthermore, we summarize the various approaches of drone remote sensing to surveying forests, mapping canopy gaps, measuring forest canopy height, tracking forest wildfires, and supporting intensive forest management. The benefits of drone remote sensing include low material and operational costs, flexible control of spatial and temporal resolution, high-intensity data collection, and the absence of risk to crews. The current forestry applications of drone remote sensing are still at an experimental stage, but they are expected to expand rapidly. To better guide the development of drone remote sensing for sustainable forestry, it is important to systematically and continuously conduct comparative studies to determine the appropriate drone remote sensing technologies for various forest conditions and/or forestry applications.

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“…Forests provide a number of ecosystem services, such as improving soil water infiltration conditions, soil erosion control and provision of wood-related products like timber and fuelwood (Calder, 2005;Ong et al, 2006). The fertility potential of soils under forests and the need to increase crop production makes forests a target for conversion to agricultural land through deforestation (Laurance et al, 2014;Pope et al, 2015). There is therefore high competition for land between forests and agricultural production in some regions of the world, particularly in the tropics (Laurance et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

Modelling the impact of agroforestry on hydrology of Mara River Basin in East Africa

Mwangi

Jülich

Patil

et al. 2016

Hydrological Processes

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Land‐use change is one of the main drivers of watershed hydrology change. The effect of forestry related land‐use changes (e.g. afforestation, deforestation, agroforestry) on water fluxes depends on climate, watershed characteristics and spatial scale. The Soil and Water Assessment Tool (SWAT) model was calibrated, validated and used to simulate the impact of agroforestry on the water balance in the Mara River Basin (MRB) in East Africa. Model performance was assessed by Nash–Sutcliffe Efficiency (NSE) and Kling–Gupta Efficiency (KGE). The NSE (and KGE) values for calibration and validation were: 0.77 (0.88) and 0.74 (0.85) for the Nyangores sub‐watershed, and 0.78 (0.89) and 0.79 (0.63) for the entire MRB. It was found that agroforestry in the watershed would generally reduce surface runoff, mainly because of enhanced infiltration. However, it would also increase evapotranspiration and consequently reduce baseflow and overall water yield, which was attributed to increased water use by trees. Spatial scale was found to have a significant effect on water balance; the impact of agroforestry was higher at the smaller headwater catchment (Nyangores) than for the larger watershed (entire MRB). However, the rate of change in water yield with an increase in area under agroforestry was different for the two and could be attributed to the spatial variability of climate within the MRB. Our results suggest that direct extrapolation of the findings from a small sub‐catchment to a larger watershed may not always be accurate. These findings could guide watershed managers on the level of trade‐offs that might occur between reduced water yields and other benefits (e.g. soil erosion control, improved soil productivity) offered by agroforestry. Copyright © 2016 John Wiley & Sons, Ltd.

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Deforestation of montane cloud forest in the Central Highlands of Guatemala: contributing factors and implications for sustainability in Q’eqchi’ communities

Cited by 21 publications

References 37 publications

Perspectives of Remote Sensing and GIS Applications in Tropical Forest Management

Perspectives of Remote Sensing and GIS Applications in Tropical Forest Management

Drone remote sensing for forestry research and practices

Modelling the impact of agroforestry on hydrology of Mara River Basin in East Africa

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