Long-term impact and biological recovery in a deep-sea mining track

Daniel O. B. Jones; Maria Belen Arias; Loïc Van Audenhaege; Sabena Blackbird; Corie Boolukos; Guadalupe Bribiesca-Contreras; Jonathan T. Copley; Andrew Dale; Susan Evans; Bethany F. M. Fleming; Andrew R. Gates; Hannah Grant; Mark G. J. Hartl; Veerle A. I. Huvenne; Rachel M. Jeffreys; Pierre Josso; Lucas D. King; Erik Simon-Lledó; Tim Le Bas; Louisa Norman; Bryan O'Malley; Thomas Peacock; Tracy Shimmield; Eva C. D. Stewart; Andrew K. Sweetman; Catherine Wardell; Dmitry Aleynik; Adrian G. Glover

doi:10.1038/s41586-025-08921-3

Long-term impact and biological recovery in a deep-sea mining track

Daniel O. B. Jones, Maria Belen Arias, Loïc Van Audenhaege, Sabena Blackbird, Corie Boolukos, Guadalupe Bribiesca-Contreras, Jonathan T. Copley, Andrew Dale, Susan Evans, Bethany F. M. Fleming, Andrew R. Gates, Hannah Grant, Mark G. J. Hartl, Veerle A. I. Huvenne, Rachel M. Jeffreys, Pierre Josso, Lucas D. King, Erik Simon-Lledó, Tim Le Bas, Louisa NormanBryan O'Malley, Thomas Peacock, Tracy Shimmield, Eva C. D. Stewart, Andrew K. Sweetman, Catherine Wardell, Dmitry Aleynik, Adrian G. Glover

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Abstract

Deep-sea polymetallic nodule mining is in the exploration phase at present with some groups proposing a move towards extraction within years. Management of this industry requires evidence of the long-term effects on deep-sea ecosystems, but the ability of seafloor ecosystems to recover from impacts over decadal scales is poorly understood. Here we show that, four decades after a test mining experiment that removed nodules, the biological impacts in many groups of organisms are persistent, although populations of several organisms, including sediment macrofauna, mobile deposit feeders and even large-sized sessile fauna, have begun to re-establish despite persistent physical changes at the seafloor. We also reveal that areas affected by plumes from this small-scale test have limited detectable residual sedimentation impacts with some biological assemblages similar in abundance compared to control areas after 44 years. Although some aspects of the modern collector design may cause reduced physical impact compared to this test mining experiment, our results show that mining impacts in the abyssal ocean will be persistent over at least decadal timeframes and communities will remain altered in directly disturbed areas, despite some recolonization. The long-term effects seen in our study provide critical data for effective management of mining activities, if they occur, including minimizing direct impacts and setting aside an effective network of protected areas.

Original language	English
Article number	26808
Journal	Nature
Early online date	26 Mar 2025
DOIs	https://doi.org/10.1038/s41586-025-08921-3
Publication status	E-pub ahead of print - 26 Mar 2025

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Jones, D. O. B., Arias, M. B., Van Audenhaege, L., Blackbird, S., Boolukos, C., Bribiesca-Contreras, G., Copley, J. T., Dale, A., Evans, S., Fleming, B. F. M., Gates, A. R., Grant, H., Hartl, M. G. J., Huvenne, V. A. I., Jeffreys, R. M., Josso, P., King, L. D., Simon-Lledó, E., Le Bas, T., ... Glover, A. G. (2025). Long-term impact and biological recovery in a deep-sea mining track. Nature, Article 26808. Advance online publication. https://doi.org/10.1038/s41586-025-08921-3

@article{3877fbcbb80e4112a29817e45972644b,

title = "Long-term impact and biological recovery in a deep-sea mining track",

abstract = "Deep-sea polymetallic nodule mining is in the exploration phase at present with some groups proposing a move towards extraction within years. Management of this industry requires evidence of the long-term effects on deep-sea ecosystems, but the ability of seafloor ecosystems to recover from impacts over decadal scales is poorly understood. Here we show that, four decades after a test mining experiment that removed nodules, the biological impacts in many groups of organisms are persistent, although populations of several organisms, including sediment macrofauna, mobile deposit feeders and even large-sized sessile fauna, have begun to re-establish despite persistent physical changes at the seafloor. We also reveal that areas affected by plumes from this small-scale test have limited detectable residual sedimentation impacts with some biological assemblages similar in abundance compared to control areas after 44 years. Although some aspects of the modern collector design may cause reduced physical impact compared to this test mining experiment, our results show that mining impacts in the abyssal ocean will be persistent over at least decadal timeframes and communities will remain altered in directly disturbed areas, despite some recolonization. The long-term effects seen in our study provide critical data for effective management of mining activities, if they occur, including minimizing direct impacts and setting aside an effective network of protected areas.",

author = "Jones, {Daniel O. B.} and Arias, {Maria Belen} and {Van Audenhaege}, Lo{\"i}c and Sabena Blackbird and Corie Boolukos and Guadalupe Bribiesca-Contreras and Copley, {Jonathan T.} and Andrew Dale and Susan Evans and Fleming, {Bethany F. M.} and Gates, {Andrew R.} and Hannah Grant and Hartl, {Mark G. J.} and Huvenne, {Veerle A. I.} and Jeffreys, {Rachel M.} and Pierre Josso and King, {Lucas D.} and Erik Simon-Lled{\'o} and {Le Bas}, Tim and Louisa Norman and Bryan O'Malley and Thomas Peacock and Tracy Shimmield and Stewart, {Eva C. D.} and Sweetman, {Andrew K.} and Catherine Wardell and Dmitry Aleynik and Glover, {Adrian G.}",

year = "2025",

month = mar,

day = "26",

doi = "10.1038/s41586-025-08921-3",

language = "English",

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Jones, DOB, Arias, MB, Van Audenhaege, L, Blackbird, S, Boolukos, C, Bribiesca-Contreras, G, Copley, JT, Dale, A, Evans, S, Fleming, BFM, Gates, AR, Grant, H, Hartl, MGJ, Huvenne, VAI, Jeffreys, RM, Josso, P, King, LD, Simon-Lledó, E, Le Bas, T, Norman, L, O'Malley, B, Peacock, T, Shimmield, T, Stewart, ECD, Sweetman, AK, Wardell, C, Aleynik, D & Glover, AG 2025, 'Long-term impact and biological recovery in a deep-sea mining track', Nature. https://doi.org/10.1038/s41586-025-08921-3

TY - JOUR

T1 - Long-term impact and biological recovery in a deep-sea mining track

AU - Jones, Daniel O. B.

AU - Arias, Maria Belen

AU - Van Audenhaege, Loïc

AU - Blackbird, Sabena

AU - Boolukos, Corie

AU - Bribiesca-Contreras, Guadalupe

AU - Copley, Jonathan T.

AU - Dale, Andrew

AU - Evans, Susan

AU - Fleming, Bethany F. M.

AU - Gates, Andrew R.

AU - Grant, Hannah

AU - Hartl, Mark G. J.

AU - Huvenne, Veerle A. I.

AU - Jeffreys, Rachel M.

AU - Josso, Pierre

AU - King, Lucas D.

AU - Simon-Lledó, Erik

AU - Le Bas, Tim

AU - Norman, Louisa

AU - O'Malley, Bryan

AU - Peacock, Thomas

AU - Shimmield, Tracy

AU - Stewart, Eva C. D.

AU - Sweetman, Andrew K.

AU - Wardell, Catherine

AU - Aleynik, Dmitry

AU - Glover, Adrian G.

PY - 2025/3/26

Y1 - 2025/3/26

N2 - Deep-sea polymetallic nodule mining is in the exploration phase at present with some groups proposing a move towards extraction within years. Management of this industry requires evidence of the long-term effects on deep-sea ecosystems, but the ability of seafloor ecosystems to recover from impacts over decadal scales is poorly understood. Here we show that, four decades after a test mining experiment that removed nodules, the biological impacts in many groups of organisms are persistent, although populations of several organisms, including sediment macrofauna, mobile deposit feeders and even large-sized sessile fauna, have begun to re-establish despite persistent physical changes at the seafloor. We also reveal that areas affected by plumes from this small-scale test have limited detectable residual sedimentation impacts with some biological assemblages similar in abundance compared to control areas after 44 years. Although some aspects of the modern collector design may cause reduced physical impact compared to this test mining experiment, our results show that mining impacts in the abyssal ocean will be persistent over at least decadal timeframes and communities will remain altered in directly disturbed areas, despite some recolonization. The long-term effects seen in our study provide critical data for effective management of mining activities, if they occur, including minimizing direct impacts and setting aside an effective network of protected areas.

AB - Deep-sea polymetallic nodule mining is in the exploration phase at present with some groups proposing a move towards extraction within years. Management of this industry requires evidence of the long-term effects on deep-sea ecosystems, but the ability of seafloor ecosystems to recover from impacts over decadal scales is poorly understood. Here we show that, four decades after a test mining experiment that removed nodules, the biological impacts in many groups of organisms are persistent, although populations of several organisms, including sediment macrofauna, mobile deposit feeders and even large-sized sessile fauna, have begun to re-establish despite persistent physical changes at the seafloor. We also reveal that areas affected by plumes from this small-scale test have limited detectable residual sedimentation impacts with some biological assemblages similar in abundance compared to control areas after 44 years. Although some aspects of the modern collector design may cause reduced physical impact compared to this test mining experiment, our results show that mining impacts in the abyssal ocean will be persistent over at least decadal timeframes and communities will remain altered in directly disturbed areas, despite some recolonization. The long-term effects seen in our study provide critical data for effective management of mining activities, if they occur, including minimizing direct impacts and setting aside an effective network of protected areas.

UR - http://www.scopus.com/inward/record.url?scp=105003981024&partnerID=8YFLogxK

U2 - 10.1038/s41586-025-08921-3

DO - 10.1038/s41586-025-08921-3

M3 - Article

C2 - 40139245

SN - 0028-0836

JO - Nature

JF - Nature

M1 - 26808

ER -

Long-term impact and biological recovery in a deep-sea mining track

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