Extent of impact of deep-sea nodule mining midwater plumes is influenced by sediment loading, turbulence and thresholds

Muñoz-Royo, Carlos; Peacock, Thomas; Alford, Matthew H.; Smith, Jerome A.; Boyer, Arnaud Le; Kulkarni, Chinmay S.; Lermusiaux, Pierre F. J.; Haley, Patrick J.; Mirabito, Chris; Wang, Dayang; Adams, E. Eric; Ouillon, Raphael; Breugem, Alexander; Decrop, Boudewijn; Lanckriet, Thijs; Supekar, Rohit; Rzeznik, Andrew; Gartman, Amy; Ju, Se‐Jong

doi:10.1038/s43247-021-00213-8

Cited by 53 publications

(64 citation statements)

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“…The Multiresolution primitive equation regional ocean modeling system (MIT-MSEAS) model was used to predict the plume dispersion, i.e., direction, velocity, and concentration. Good agreement was found between the MIT-MSEAS model and the PLUMEX field experiments [23];…”

Section: Introductionmentioning

confidence: 70%

“…The main differences between the two discharge sources in a polymetallic nodule mining operation are the orientation (vertical from the VTS and mostly horizontal from the PNMT), distance to the seabed, flow rate, and concentration of the suspended sediments. Some studies showed that the SWOE discharge location ranges from near the seabed to just below the oxygen minimum layer (800-1000 m water depth) [5,7,8,21], while the distance to the seabed of a PNMT depends on the discharge position on the PNMT, ranging from 1-3 m. The SWOE discharge flow rate and concentration are estimated to be about 0.56 m 3 /s and 8 g/L, respectively [21,23]. Table 1 shows the estimated solid flux rate and sediment concentration range of a PNMT discharge.…”

Section: Overviewmentioning

confidence: 99%

“…In the last few decades, valuable insight has been gained into DSM processes through various projects, where the environmental impacts of DSM were investigated, e.g., Refs. [5,9,10,13,17,[19][20][21][22][23]. Some of the DSM research projects are mentioned as follows:…”

Section: Introductionmentioning

confidence: 99%

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Near-Field Analysis of Turbidity Flows Generated by Polymetallic Nodule Mining Tools

Elerian

Alhaddad

Helmons

et al. 2021

Mining

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The interest in polymetallic nodule mining has considerably increased in the last few decades. This has been largely driven by population growth and the need to move towards a green future, which requires strategic raw materials. Deep-Sea Mining (DSM) is a potential source of such key materials. While harvesting the ore from the deep sea by a Polymetallic Nodule Mining Tool (PNMT), some bed sediment is unavoidably collected. Within the PNMT, the ore is separated from the sediment, and the remaining sediment–water mixture is discharged behind the PNMT, forming an environmental concern. This paper begins with surveying the state-of-the-art knowledge of the evolution of the discharge from a PNMT, in which the discharge characteristics and generation of turbidity currents are discussed. Moreover, the existing water entrainment theories and coefficients are analyzed. It is shown how plumes and jets can be classified using the flux balance approach. Following that, the models of Lee et al. (2013) and Parker et al. (1986) are combined and utilized to study the evolution of both the generated sediment plume and the subsequent turbidity current. The results showed that a smaller sediment flux at the impingement point, where the plume is transformed into a turbidity current, results in a shorter run-out distance of the turbidity current, consequently being more favorable from an environmental point of view.

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Section: Introductionmentioning

confidence: 70%

Section: Overviewmentioning

confidence: 99%

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Near-Field Analysis of Turbidity Flows Generated by Polymetallic Nodule Mining Tools

Elerian

Alhaddad

Helmons

et al. 2021

Mining

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“…In addition, accidental waste spills of deep-sea sediment from the mining platform or riser pipe will most likely affect the pelagic environment. To date, the magnitude of the impact generated by mining activity is still unpredictable, as a full-scale mining test that includes a discharge into the midwater column has not yet been performed (Christiansen et al, 2020;Muñoz-Royo et al, 2021). Based on an estimation of 260 days per year of operation, a mining vessel could release up to 1.2 × 10 8 kg of sediment in the water column (Muñoz-Royo et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

“…To date, the magnitude of the impact generated by mining activity is still unpredictable, as a full-scale mining test that includes a discharge into the midwater column has not yet been performed (Christiansen et al, 2020;Muñoz-Royo et al, 2021). Based on an estimation of 260 days per year of operation, a mining vessel could release up to 1.2 × 10 8 kg of sediment in the water column (Muñoz-Royo et al, 2021). It has been suggested that a sediment plume released in the epipelagic layer will increase turbidity and decrease light penetration, resulting in a net decrease in primary productivity.…”

Section: Introductionmentioning

confidence: 99%

Vertical Distribution of Particulate Matter in the Clarion Clipperton Zone (German Sector)—Potential Impacts From Deep-Sea Mining Discharge in the Water Column

et al. 2022

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Most studies on the potential impacts of deep-sea mining in the Clarion Clipperton Zone (CCZ) have largely focused on benthic ecosystems but ignore the pelagic environment. To model full-scale impacts, it is important to understand how sediment discharge might affect the pelagic zone as well. This study combines in situ optics, hydrography, and remote sensing to describe particle abundance and size distribution through the entire water column in the CCZ (German sector). CCZ surface waters were characterized as productive over the year. During the winter, we observed the formation of a sharp transition zone in Chla concentration, identifying the area as a productive transitional zone toward a more depleted ocean gyre. In the German sector, median particle size was small (± 77 μm), and large particles (>300 μm) were rare. By assessing particle flux attenuation, we could show that the presence of a thick oxygen minimum zone (OMZ) plays an essential role in export and transformation of settling aggregates, with strong diel variations. We suggest that the combination of small aggregate size, bottom currents and slow seafloor consolidation may explain the extremely low sedimentation rate in the CCZ. We conclude that sediment incorporations and ballasting effect on settling particulate matter represent the most significant hazard on midwater and benthic ecosystems.

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Ethical opportunities in deep‐sea collection of polymetallic nodules from the Clarion‐Clipperton Zone

Katona

Paulikas

Stone

2021

Integr Envir Assess & Manag

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Infrastructure supporting the transition of human societies from fossil fuels to renewable energy will require hundreds of millions of tons of metals. Polymetallic nodules on the abyssal seabed of the Clarion‐Clipperton Zone (CCZ), eastern North Pacific Ocean, could provide them. We focus on ethical considerations and opportunities available to the novel CCZ nodule‐collection industry, integrating robust science with strong pillars of social and environmental responsibility. Ethical considerations include harm to sea life and recovery time, but also the value of human life, indigenous rights, rights of nature, animal rights, intrinsic values, and intangible ecosystem services. A “planetary perspective” considers the biosphere, hydrosphere, and atmosphere, extends beyond mineral extraction to a life‐cycle view of impacts, and includes local, national, and global impacts and stakeholders. Stakeholders include direct nodule‐collection actors, ocean conservationists, companies, communities, interest groups, nations, and citizens globally, plus counterfactual stakeholders involved with or affected by intensification of terrestrial mining if ocean metals are not used. Nodule collection would harm species and portions of ecosystems, but could have lower life‐cycle impacts than terrestrial mining expansion, especially if nodule‐metal producers explicitly design for it and stakeholders hold them accountable. Participants across the value chain can elevate the role of ethics in strategic objective setting, engineering design optimization, commitments to stakeholders, democratization of governance, and fostering of circular economies. The International Seabed Authority is called to establish equitable and transparent distribution of royalties and gains, and continue engaging scientists, economists, and experts from all spheres in optimizing deep‐sea mineral extraction for humans and nature. Nodule collection presents a unique opportunity for an ambitious reset of ecological norms in a nascent industry. Embracing ethical opportunities can set an example for industrial‐scale activities on land and sea, accelerate environmental gains through environmental competition with land ores, and hasten civilization's progress toward a sustainable future. Integr Environ Assess Manag 2022;18:634–654. © 2021 The Authors. Integrated Environmental Assessment and Management published by Wiley Periodicals LLC on behalf of Society of Environmental Toxicology & Chemistry (SETAC).

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Extent of impact of deep-sea nodule mining midwater plumes is influenced by sediment loading, turbulence and thresholds

Cited by 53 publications

References 60 publications

Near-Field Analysis of Turbidity Flows Generated by Polymetallic Nodule Mining Tools

Near-Field Analysis of Turbidity Flows Generated by Polymetallic Nodule Mining Tools

Vertical Distribution of Particulate Matter in the Clarion Clipperton Zone (German Sector)—Potential Impacts From Deep-Sea Mining Discharge in the Water Column

Ethical opportunities in deep‐sea collection of polymetallic nodules from the Clarion‐Clipperton Zone

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