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Nature Conservation 56: 77-82 (2024)
DOI: 10.3897/natureconservation.56.133441

Letter To The Editor

Eight years after the Fundao tailings dam collapse:
chaos on the muddy banks

Cassio Cardoso Pereira'’”©, Stephannie Fernandes*®, Geraldo Wilson Fernandes'24®,

Fernando Figueiredo Goulart*®

ee wo NY —

Horizonte, MG, Brazil

Universidade Federal de Minas Gerais, 31270-901, Belo Horizonte, MG, Brazil

Knowledge Center for Biodiversity, 31270-901, Belo Horizonte, MG, Brazil

Department of Global & Sociocultural Studies and Kimberly Green Latin American and Caribbean Center, Florida International University, 33199, Miami, FL, USA
Laboratorio de Ecologia Evolutiva & Biodiversidade, Departamento de Genética, Ecologia e Evolugao, Universidade Federal de Minas Gerais, 31270-901, Belo

Corresponding author: Cassio Cardoso Pereira (cassiocardosopereira@gmail.com)

OPEN Qaceess

Academic editor: Klaus Henle
Received: 9 May 2024
Accepted: 3 August 2024
Published: 20 August 2024

ZooBank: https://zoobank.
org/674AF3BE-F4A3-49C3-A9A2-
10F5F4493F5C

Citation: Pereira CC, Fernandes S,
Fernandes GW, Goulart FF (2024)
Eight years after the Fundao tailings
dam collapse: chaos on the muddy
banks. Nature Conservation 56:
77-82. https://doi.org/10.3897/
natureconservation.96.133441

Copyright: © Cassio Cardoso Pereira et al.
This is an open access article distributed under
terms of the Creative Commons Attribution

License (Attribution 4.0 International - CC BY 4.0).

Key words: Biodiversity, Brumadinho, Fundao tailings dam, Mariana dam disaster

Eight years have passed since Brazil's worst environmental disaster, the
collapse of the Samarco company’s Fundao tailings dam in Mariana, Minas
Gerais, Brazil. The mud spill buried the village of Bento Rodrigues and affected,
with mud full of heavy metals and metalloids, more than 600 km of the river
channel, and marginal habitats. It extended for hundreds of kilometers along
the coast, disturbing the sea, coral reefs, mangroves, and beaches (Fernandes
et al. 2016; Costa et al. 2022). At the time of the disaster, more than one million
people across 35 cities were affected due to the spill of around 50 million m° of
mud waste, resulting in 19 deaths, diseases, and hundreds of people displaced
(Fernandes et al. 2016; Omachi et al. 2018).

The dam breach unleashed a cascade of health and social woes for people
living in the area. High levels of heavy metals were found in the blood and urine
of riverside populations (Paulelli et al. 2022). There was an increase in diseas-
es arising from habitat degradation, when people are exposed to mosquitoes,
such as dengue'’s transmitters, as well as enteric pathogens in the water along
the Doce River (Nishijima and Rocha 2020). Finally, the livelihoods, health, and
culture of indigenous peoples, such as the Krenak, Tupiniquim, Guaranis, and
Quilombola populations (afro-descendant communities, predominantly com-
posed of the rural and urban black population) were profoundly affected by the
disaster (Oliveira et al. 2020; Zhouri and Pascoal 2022).

The ecological devastation mirrored the human tragedy (Fig. 1). Approx-
imately 346 endangered species on the mainland were negatively impacted
by the disaster (Knopff et al. 2020), and increased the risk of extinction of 13
aquatic species, becoming a major threat to three of them (Drummond et al.
2021). Furthermore, there were unexpected impacts such as the bioaccumu-
lation of pesticides in endangered Franciscana dolphin [Pontoporia blainvillei
(Gervais & d’Orbigny, 1844)], as the mud tsunami stirred up historic deposits
of these pollutants from soil and river sediments (Nascimento et al. 2022).

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Cassio Cardoso Pereira et al.: Chaos on the muddy banks

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Figure 1. Dead fish in Marliéria, Minas Gerais, Brazil, about 200 km downstream from the Fundao tailings dam. Photo

credit: Elvira Nascimento.

To make it worse, heavy summer rains re-suspend contaminants in the conti-
nent, while winter cold fronts suspend pollutants from the bottom of the sea
every year (Fernandes et al. 2022).

Another major concern is invasive alien species. Studies have shown that
changes in the substrate and water quality altered the composition of the as-
semblage of fish, copepods, and rotifers, favoring non-native species from
these groups (Programa de Monitoramento da Biodiversidade Aquatica 2021).
Furthermore, another indirect impact of contamination on lake communities
was the invasion of water hyacinth (Eichhornia sp.), which increased in lakes
and ponds, with a high correlation with increases in the concentration of vana-
dium, iron, and zinc found in the water (Programa de Monitoramento da Biodi-
versidade Aquatica 2021).

Finally, it is worth highlighting the challenge of restoring ecosystems. Remov-
ing all the waste that has spread throughout the basin is practically impossible,
but the longer the recovery actions take, the greater the risk that the river will
be contaminated again by the mud that is still on the banks, especially during
periods of rain. To prevent this from happening, the recovery of the riparian
forest must be prioritized. For now, emergency actions are being undertaken to
try to prevent the mud from flowing into the river, with the planting of grasses
and legume trees that would have the function of keeping the land on the bank
firmer. However, many of these species are exotic (personal observation) and
this brings future environmental problems, unbalancing the entire ecosystem.
Even the use of native species can be problematic because by introducing a

Nature Conservation 56: 77-82 (2024), DOI: 10.3897/natureconservation.56.133441 78

Cassio Cardoso Pereira et al.: Chaos on the muddy banks

limited number of species into a given region, we can inadvertently reduce the
ecological functionality of the environment, making it more homogeneous and
less diverse (Pereira et al. 2024; Toma et al. 2024). Therefore, the restoration
of vegetation in the Rio Doce basin needs to be carried out with a diverse range
of native species so that environmental connectivity and restoration of the im-
portant ecosystem services on which we depend are more quickly promoted
(Pereira et al., 2024; Ramos et al., 2024; Toma et al. 2024).

Specific efforts to compensate for socio-environmental impacts have been
made by Renova since 2016, a foundation created to repair and compensate for
the impacts of Fundao. The foundation has been building housing, compensat-
ing residents, and trying to help the affected human populations. However, the
process has been very slow and controversial (Losekann and Milanez 2023).
Conveniently, the company creates its foundation to repair its own damages.
The government should be imposing several measures to solve the problems,
demanding reports, assessments and results on what should be done. In other
words, it is not right that the company chooses its own professionals to assess
these damages. This oversight should be impartial and carried out by the gov-
ernment. Local representatives, research institutions, and NGOs should also
have a say in what Renova is doing. It is of utmost importance to develop and
implement a comprehensive program to provide the necessary assistance to
affected families, in addition to implementing a comprehensive restoration and
recovery program that would accelerate efforts and go beyond punctual efforts.

All mitigation measures may be wasted if the causes of such catastrophes
are not addressed. The Mariana accident was repeated in Brumadinho, claiming
272 lives (Vidal et al. 2024). This brought to the fore the discussion about the
need to find alternatives for mining activities in the country, which has 839 tail-
ings dams (Agéncia Nacional de Mineracao 2024). A law was created in Minas
Gerais (Law No. 23,291, of 25/02/2019, Sistema Integrado de Informacao Am-
biental 2019) that prevents the construction, installation, expansion, or raising
of dams where there is a community in the so-called self-rescue zone: the por-
tion of the valley downstream of the dam where there is no time to intervene in
an emergency situation. However, these laws do not appear to be obeyed and
dams may still be built if there is no alternative method.

The best way to replace the problematic tailings dams is dry mining (Davies
and Rice 2001). Dry ore beneficiation is ideal because it allows the ore to be
processed with very little or no water. In other words, the leftovers from the ore
beneficiation are filtered and placed in large piles, replacing the use of tradition-
al dams. Dry mining also makes it possible to generate a substrate that can be
used in the production of new products, including sand for asphalt paving and
bricks for civil construction. In addition, this substrate can be vegetated and, in
this way, contribute to the recovery of nature (Davies and Rice 2001). However,
this method of beneficiating the ore is much more expensive and, unfortunate-
ly, there are still several active tailings dams in Brazil, many of them upstream
and in critical condition. It is important to emphasize that it is not enough to
simply deactivate these dams, as the mud remains stored and the dam could
break at any time. Heavy rains can generate floods that could rupture the res-
ervoir. Unfortunately, a common practice among mining companies is to hire
technicians to assess the condition of their dams and the risk of rupture. This is
as incoherent as “putting a fox to guard a henhouse’”. It is up to the government

Nature Conservation 56: 77-82 (2024), DOI: 10.3897/natureconservation.56.133441 79

Cassio Cardoso Pereira et al.: Chaos on the muddy banks

to inspect all of this and do an impartial and thorough assessment. Therefore,
in addition to replacing the dams with a more modern and safer tailings pro-
cessing system, it is essential that these dams be monitored and emptied to
prevent overflows.

The mud spill is still affecting lives, health, economy, culture, and biodiver-
sity. Over the years, the impact has increased in intensity, severity, and area,
ranking as one of the major environmental disasters worldwide. In association
with other threats such as climate change that induce extreme events such as
cyclones and heavy rains, which foster pollutant resuspension, Fundao spills
are even more worrisome to terrestrial and aquatic species in a wide range of
globally important sites for conservation, as well as for human population that
depend on these ecosystems.

The path to healing the Rio Doce requires a multi-pronged approach. Effec-
tive public policies are essential, encompassing compensation for affected
communities, restoration initiatives, and long-term conservation programs.
These policies, rooted in current scientific research, should prioritize rebuilding
resilient ecosystems and river protections. Collaboration is paramount. Local
and indigenous communities hold invaluable knowledge of the Rio Doce and
fostering their inclusion provides a sense of ownership over its revival. Partner-
ing with scientific experts ensures evidence-based restoration strategies and
tracks their effectiveness. By implementing these solutions and supporting a
collaborative conservation strategy, the long journey to heal the Rio Doce eco-
system and the lives it sustains can truly begin.

Acknowledgements

The authors thank UFMG, CNPgq, Fapemig, and CAPES for their continuous support.

Additional information

Conflict of interest

The authors have declared that no competing interests exist.

Ethical statement

No ethical statement was reported.

Funding

Cassio Cardoso Pereira thanks scholarship from CNPq (173800/2023-8). Geraldo Wil-
son Fernandes thanks CNPq, Knowledge Center for Biodiversity (CNPq; 406757/2022-
4), MCTI and FAPEMIG for grant support. Fernando Figueiredo Goulart thanks FINEP for
the DTI (Development, Technology and Innovation) scholarship and the Camara Técnica
de Biodiversidade CTBio/FLACSO/Renova (N° 002/2022).

Author contributions

Cassio Cardoso Pereira, Geraldo Wilson Fernandes, and Fernando Figueiredo Goulart con-
ceived the ideas; Cassio Cardoso Pereira and Fernando Figueiredo Goulart led the writing
of the manuscript. Stephannie Fernandes made edits and also contributed to the main
text. All authors contributed critically to the drafts and gave final approval for publication.

Nature Conservation 56: 77-82 (2024), DOI: 10.3897/natureconservation.56.133441 80

Cassio Cardoso Pereira et al.: Chaos on the muddy banks

Author ORCIDs

Cassio Cardoso Pereira © https://orcid.org/0000-0002-601 7-4083
Stephannie Fernandes © https://orcid.org/0000-0002-2049-1164
Geraldo Wilson Fernandes ® https://orcid.org/0000-0003-1 559-6049
Fernando Figueiredo Goulart © https://orcid.org/0000-0002-6327-5285

Data availability

All of the data that support the findings of this study are available in the main text.

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