MAAP #169: Mining on Top of Yapacana Tepui (Yapacana National Park, Venezuela)

Figure 1. Active mining on top of Yapacacan tepui in the Venezuelan Amazon. Data: Planet/NICFI (level 2), ACA/MAAP,

Tepuis are stunning table-top mountains found in northern South America. They are considered sacred by indigenous groups of the region; in fact, the word tepui means “house of the gods” in a local indigenous language. Tepuis also have high levels of endemism since they are not connected to other ranges.

However, we have documented active mining operations on top of the Yapacana tepui, located within Yapacana National Park in the Venezuelan Amazon.

In Figure 1 (to the right), observe the Yapacana tepui surrounded by active gold mining operations in Yapacana National Park. Also, note the mining activities on top of the tepui.

As detailed below, by analyzing very high-resolution satellite imagery (Skysat), we found 425 mining data points (including mining camps and machinery) on top of the tepui, indicating rampant mining on this important, and supposedly protected, biogeographical site.

Note that this is in addition to the 8,000 mining data points documented in the surrounding lowlands of Yapacana National Park  (see MAAP #156).

Mining on Top of Yapacana Tepui

Figure 2 serves as our base map, zooming in and showing the top of the tepui without and with the mining data (left and right panel, respectively). Note how the second image brings out previously “invisible” elements within the overall mining area: 425 mining data points (322 camps and 103 pieces of equipment).  Further below are additional Zooms A-C to better visualize the mining camps and equipment with the actual Skyat imagery. Click twice to fully enlarge images below.

Figure 2. Yapacana tepui without (left panel) and with (right panel) the mining data. Data: Planet/NICFI (level 2), ACA/MAAP. Click twice to fully enlarge.

Zoom A

Zoom A. Mining equipment and camps on Yapacana tepui, without (left panel) and with (right panel) the mining data. Data: Planet, ACA/MAAP. Click twice to fully enlarge.

Zoom B

Zoom B. Mining equipment and camps on Yapacana tepui, without (left panel) and with (right panel) the mining data. Data: Planet, ACA/MAAP. Click twice to fully enlarge.

Zoom C

Zoom C. Mining equipment and camps on Yapacana tepui, without (left panel) and with (right panel) the mining data. Data: Planet, ACA/MAAP. Click twice to fully enlarge.

Zoom D

Zoom D. Mining equipment and camps on Yapacana tepui, without (left panel) and with (right panel) the mining data. Data: Planet, ACA/MAAP. Click twice to fully enlarge.

Zoom E

Zoom E. Mining equipment and camps on Yapacana tepui, without (left panel) and with (right panel) the mining data. Data: Planet, ACA/MAAP. Click twice to fully enlarge.

Methodology

We tasked very high-resolution Skysat satellite imagery (0.5 meters), using the host company Planet’s tasking dashboard, for the Yapacana tepui. We then closely and manually analyzed these images, documenting both mining camps and equipment. We researched aerial examples of mining areas in other countries to improve our identification abilities.

Acknowledgements

We thank the organization SOSOrinoco for important information and comments related to this report.

Citation

Finer M, Mamani N (2022) Mining on Top of Yapacana Tepui (Yapacana National Park, Venezuela). MAAP: 169.

MAAP #161: Soy Deforestation in the Brazilian Amazon

Example of fires burning an area recently deforested for a new soy plantation. Data: Planet.

The Amazon Soy Moratorium has often been credited with significantly reducing soy-related deforestation in the Amazon over the past 15 years.

The Moratorium is a voluntary zero-deforestation agreement in which traders agree not to purchase soy grown on land cleared after 2008.

However, increasing soybean prices may be driving a resurgence of the problem of direct soy deforestation. That is, direct conversion of primary deforestation to soy plantation without passing an initial period as cattle pasture.

A recent report by Global Forest Watch estimated the direct soy deforestation of 29,000 hectares in the Brazilian Amazon in 2019 (Schneider et al 2021).

Here, we report the additional direct soy deforestation of at least 42,000 hectares in the Brazilian Amazon since 2020. All of these areas occurred in the state of Mato Grosso, located on the southeast edge of the Amazon.

We detected all of these soy plantations based on recent major fire activity (84 major fires), in which the recently deforested area was burned in preparation for the upcoming planting season (see Methodology below for more details).

Below, we show a base map of these recently deforested and then burned areas in the Mato Grosso state of the Brazilian Amazon followed by a series of examples from the satellite imagery.

Base Map – Recent Soy Deforestation in Brazilian Amazon

The Base Map below shows the areas, indicated by red dots, of recent direct deforestation for new soy plantations that we detected by monitoring major fire activity in 2022.

Between May 2021 and June 2022, we detected 84 major fires that corresponded to burning areas recently deforested for new soy plantations. These 84 areas, all of which occurred in the state of Mato Grosso, cover an area of 42,000 hectares.

Our geographic focus was the Brazilian Amazon biome in the state of Mato Grosso, as covered by the Amazon Soy Moratorium. For example, we also documented extensive direct soy deforestation and fire in the Bolivian Amazon (Santa Cruz department), but we did not include that information here.

Base Map. Recent Soy Deforestation in Brazilian Amazon. Data: ACA/MAAP, NICFI.

Examples of Deforestation & Fire for New Soy Plantations

As noted above, we detected the direct deforestation for new soy plantations by monitoring major fire activity in 2022. It is assumed that fires are preparing the recently deforested area for upcoming soy planting.

Methodology

We first tracked major fires in 2021 and 2022 using our novel real-time fire monitoring app. See MAAP #118 for more background information about the app and general methodology for detecting major fires based on aerosol emissions. The first major fires were detected in May of each year (2021 and 2022) and we continued collecting data on a daily basis through early July of each year. We monitored fires across the entire Amazon, but this report focuses on Brazil.

For all major fires detected with the app, we confirmed them with high-resolution satellite imagery from Planet. This confirmation was accomplished by visualizing either smoke plumes the day of the fire or burned areas in subsequent days after the fire.

All confirmed fires were assigned a category based on likely direct fire type or driver. These categories include 1) burning area recently deforested for new soy plantation, burning area recently deforested for new cattle pasture, and burning grasslands embedded in the larger rainforest matrix. On rarer occasions, one of these fire types may escape into the surrounding forest, making it an actual forest fire.

Specifically, the soy-related fires were defined as those burning recently deforested areas (that is, areas cleared since 2020) that had a distinctive linear pattern seemingly designed for organized crop agriculture. Most of the newly identified soy areas were also adjacent to existing soy plantations. In other words, the soy deforestation and fire pattern were visually quite distinct from cattle-related and grassland fires. Local experts have informed us that the fires are likely prepping the recently deforested area for the upcoming soy planting season. For all determined direct soy-related fires, we estimated the burned area using the spatial measurement tools in Planet Explorer and entered it into a database. We noted that in July of both years, the fires shifted away from soy and more towards cattle areas.

References

Martina Schneider, Liz Goldman, Mikaela Weisse, Luiz Amaral and Luiz Calado (2021) The Commodity Report: Soy Production’s Impact on Forests in South America. Link: https://www.globalforestwatch.org/blog/commodities/soy-production-forests-south-america/

X.-P. Song, M.C. Hansen, P. Potapov, et al (2021). Massive soybean expansion in South America since 2000 and implications for conservation. Nature Sustainability. Link: https://www.nature.com/articles/s41893-021-00729-z

Acknowledgements

We thank V. Silgueiro and R. Carvalho from the organization Instituto Centro de Vida (ICV) for helpful information and comments related to this report.

Citation

Finer M, Ariñez A (2022) Soy Deforestation in the Brazilian Amazon. MAAP: #161.

MAAP #160: Lasers Estimate Carbon in the Amazon – NASA’s GEDI Mission

Simulation of GEDI lasers collecting data. Source: UMD.

NASA’s GEDI mission uses lasers to provide cutting-edge estimates of aboveground biomass and related carbon on a global scale.

Launched in late 2018 and installed on the International Space Station, GEDI’s lasers return an estimate of aboveground biomass density at greater accuracy and resolution than previously available.

Here, we zoom in on the Amazon and take a first look at the recently available Level 4B data: Gridded Aboveground Biomass Density measured in megagrams per hectare (Mg/ha) at a 1-kilometer resolution.

See the GEDI homepage for more background information on the mission, which extends until January 2023. Be sure to check out this illustrative video.

 

 

 

 

Base Map – Aboveground Biomass in the Amazon

The Base Map displays the GEDI data for the nine countries of the Amazon biome, displaying aboveground biomass for the time period April 2019 to August 2021.

Base Map. Aboveground Biomass Density in the Amazon. Data: NASA/UMD GEDI L4B. Click twice to enlarge.

 

We highlight the following initial major findings:

  • The data is not yet comprehensive as there are some areas the lasers have not yet recorded data (indicated in white).
    h
  • The areas with the highest aboveground biomass and related carbon (indicated in dark green and purple) include:
    • Northeast Amazon: Corner of Brazil, Suriname, & French Guiana.
    • Southwest Amazon: Southwest Brazil and adjacent Peru (see zoom below).
    • Northwest Amazon: Northern Peru, Ecuador, and southeast Colombia.

Zoom In – Southwest Amazon

To better visualize the GEDI laser data, we also present a zoom of the Southwest Amazon. Although deforested areas (and natural savannahs) are illustrated in yellow and orange, note the surrounding presence of high carbon forest (green and purple).

Zoom In – Southwest Amazon. Aboveground Biomass Density. Data: NASA/UMD GEDI L4B. Click twice to enlarge.

Zoom Out – Global Scale

Note that tropical forests, including the Amazon, have the highest levels of aboveground biomass globally.

Zoom Out – Glocal scale. Aboveground Biomass Density. Data: NASA/UMD GEDI L4B. Click twice to enlarge.

Acknowledgements

This work was supported by NORAD (Norwegian Agency for Development Cooperation) and ICFC (International Conservation Fund of Canada).

Citation

Finer M, Ariñez A (2022) Lasers Estimate Carbon in the Amazon – NASA’s GEDI Mission. MAAP: 160.