Buried Cobalt-rich Ferromanganese Crusts from Weijia Guyot and their Implications for Pacific Plate Motion

Bin ZHAO; Gaowen HE; Yuhan JIANG; Shijia LIU; Si CHEN; Yinan DENG; Yong YANG; Jiangbo REN; Weilin MA; Limin ZHANG; Haifeng WANG; Kehong YANG; Xianze DENG; Qing CHEN; Ganglan ZHANG

doi:10.1111/1755-6724.15347

Acta Geologica Sinica (English Edition) ›› 2025, Vol. 99 ›› Issue (5) :1344 -1354. DOI: 10.1111/1755-6724.15347

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Buried Cobalt-rich Ferromanganese Crusts from Weijia Guyot and their Implications for Pacific Plate Motion

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Abstract

Weijia Guyot, located in the western Pacific Ocean, has become a research focus due to its abundant cobalt-rich ferromanganese (Fe-Mn) crusts. While most studies on Fe-Mn crusts on seamounts have focused on the exposed variety, less attention has been paid to potential buried crusts. This study presents a preliminary geochemical and chronological study of buried Fe-Mn crusts at Weijia Guyot. The findings suggest that these buried crusts began to form around 57.5 Ma and ceased growing at approximately 46.3 Ma. Following the formation of Weijia Guyot through volcanic eruption, it did not experience continuous and steady subsidence to its current depth. Instead, an exhumation process took place from deep to shallow depths between 46.3 and 11.6 Ma. This process brought the Fe-Mn crusts into shallow water environments, halting their growth. During this time, Weijia Guyot was located near the equatorial Pacific Ocean and was exposed to an extended period of phosphatization. This exposure led to a depletion of key metallogenic elements, such as Co, Ni and Cu, within the Fe-Mn crusts, while P₂O₅ and CaO levels increased significantly. Since the Middle Miocene, the crusts have been progressively buried by pelagic sediments.

Keywords

buried cobalt-rich ferromanganese crusts / growth rate / geochronology / seamount evolution / Weijia Guyot / western Pacific Ocean

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Bin ZHAO, Gaowen HE, Yuhan JIANG, Shijia LIU, Si CHEN, Yinan DENG, Yong YANG, Jiangbo REN, Weilin MA, Limin ZHANG, Haifeng WANG, Kehong YANG, Xianze DENG, Qing CHEN, Ganglan ZHANG. Buried Cobalt-rich Ferromanganese Crusts from Weijia Guyot and their Implications for Pacific Plate Motion. Acta Geologica Sinica (English Edition), 2025, 99(5): 1344-1354 DOI:10.1111/1755-6724.15347

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References

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[1]	Asavin, A.M., Kubrakova, I.V., Mel'nikov, M.E., and Tyutyunnik, O.A., and Chesalova, E.I., 2010. Geochemical zoning in ferromanganese crusts of Ita Mai Tai Guyot. Geochemistry International, 48: 423–445.

[2]	Boschman, L.M., and Van Hinsbergen, D.J.J., 2016. On the enigmatic birth of the Pacific Plate within the Panthalassa Ocean. Science Advances, 2: e1600022.

[3]	Deng, Y., Zhang, G., Zhao, B., He, G.W., Ren, J.B., Ma, W.L., Zhang, L.M., Yang, Y., Chen, Q., and Yang, K.H., 2024. Early diagenetic control on the enrichment and mobilization of rare earth elements and transition metals in buried ferromanganese crust. Marine Geology, 469: 107238.

[4]	Du, D., Ren, X., Yan, S., Shi, X., Liu, Y., and He, G., 2017. An integrated method for the quantitative evaluation of mineral resources of cobalt-rich crusts on seamounts. Ore Geology Reviews, 84: 174–184.

[5]	Guo, Z., Hu, Y., Du, Q., Liu, Y., Qin, G., and Peng, X., 2024. Microbial biosignatures associated with iddingsite in Hadal basalts from the southern Mariana Trench. Acta Geologica Sinica (English Edition), 98: 1501–1510.

[6]	He, G.W., Liang, D.H., Song, C.B., Wu, S., and Zhang, X., 2005. Determining the distribution boundary of cobalt-rich crusts of Guyot by synchronous application of sub-bottom profiling and deep-Sea video recording. Earth Science, 30(4): 509–512 (in Chinese with English abstract).

[7]	He, G.W., Ma, W.L., Song, C.B., Yang, S.X., Zhu, B.D., Yao, H.Q., Jiang, X., and Cheng, Y., 2011. Distribution characteristics of seamount cobalt-rich ferromanganese crusts and the determination of the size of areas for exploration and exploitation. Acta Oceanologica Sinica, 30: 63–75.

[8]	Heezen, B.C., and MacGregor, I.D., 1973a. Diagenesis of a Seamount Oolite from the West Pacific, Leg 20, DSDP. In: Initial Reports of the Deep Sea Drilling Project, 20, Initial Reports of the Deep Sea Drilling Project. U.S. Government Printing Office, 363–387.

[9]	Heezen, B.C., and MacGregor, I.D., 1973b. Oolitic limestone on the Ita Maitai Guyot, Equatorial Pacific: DSDP Site 202. In: Initial reports of the Deep Sea Drilling Project, 20, Initial Reports of the Deep Sea Drilling Project. U.S. Government Printing Office, 97–102.

[10]	Heezen, B.C., and MacGregor, I.D., 1973c. Tertiary Pelagic Ooze on Ita Maitai Guyot, Equatorial Pacific: DSDP Sites 200 and 201. In: Initial Reports of the Deep Sea Drilling Project, 20, Initial Reports of the Deep Sea Drilling Project. U.S. Government Printing Office, 87–96.

[11]	Hein, J.R., 2000. Cobalt-rich ferromanganese crusts: Global distribution, composition, origin and research activities. In: International Seabed Authority eds. Minerals other than polymetallic nodulesof the international seabed area, 26–30.

[12]	Hein, J.R., Yeh, H.W., Gunn, S.H., Sliter, W.V., Benninger, L.M., and Wang, C.H., 1993. Two major Cenozoic episodes of phosphogenesis recorded in equatorial pacific seamount deposits. Paleoceanography, 8: 293–311.

[13]	Hein, J.R., Conrad, T.A., and Dunham, R.E., 2009. Seamount characteristics and mine-site model applied to exploration and mining-lease-block selection for cobalt-rich ferromanganese crusts. Marine Georesources & Geotechnology, 27: 160–176.

[14]	Hein, J.R., Mizell, K., Koschinsky, A., and Conrad, T.A., 2013. Deep-ocean mineral deposits as a source of critical metals for high- and green-technology applications: Comparison with land-based resources. Ore Geology Reviews, 51: 1–14.

[15]	Hein, J.R., Koschinsk, A., Bau, M., Manheim, F.T., Kang, J.K., and Roberts, L., 2017. Cobalt-rich ferromanganese crusts in the Pacific. In: Cronan, D.S. (Ed.), Handbook of Marine Mineral Deposits. Routledge, 239–279.

[16]	Hirano, N., Ogawa, Y., and Saito, K., 2002. Long-lived Early Cretaceous seamount volcanism in the Mariana Trench, Western Pacific Ocean. Marine Geology, 189: 371–379.

[17]	Koppers, A.A.P., Staudigel, H., Wijbrans, J.R., and Pringle, M.S., 1998. The Magellan seamount trail: implications for Cretaceous hotspot volcanism and absolute Pacific plate motion. Earth and Planetary Science Letters, 163: 53–68.

[18]	Lee, T.G., Lee, S.M., Moon, J.W., and Lee, K., 2003. Paleomagnetic investigation of seamounts in the vicinity of Ogasawara Fracture Zone northwest of the Marshall Islands, western Pacific. Earth Planets and Space, 55: 355–360.

[19]	Lee, T.G., Hein, J.R., Lee, K., Moon, J. W., and Ko, Y.T., 2005. Sub-seafloor acoustic characterization of seamounts near the Ogasawara Fracture Zone in the western Pacific using chirp (3–7 kHz) subbottom profiles. Deep Sea Research Part I: Oceanographic Research Papers, 52: 1932–1956.

[20]	Lee, T.G., Lee, K., Hein, J.R., and Moon, J.W., 2009. Geophysical investigation of seamounts near the Ogasawara Fracture Zone, western Pacific. Earth Planets and Space, 61: 319–331.

[21]

Li, S., Cao, X., Wang, G., Liu, B., Li, X., Suo, Y., Jiang, Z., Guo, L., Zhou, J., Wang, P., Zhu, J., Wang, G., Zhao, S., Liu, Y., and Zhang, G., 2019. Meso-Cenozoic tectonic evolution and plate reconstruction of the Pacific Plate. Journal of Geomechanics, 25(05): 642–677 (in Chinese with English abstract).

[22]	Mel'nikov, M.E., Tugolesov, D.D., and Pletnev, S.P., 2010. The structure of the incoherent sediments in the Ita Mai Tai Guyot (Pacific Ocean) based on geoacoustic profiling data. Oceanology, 50: 582–590.

[23]	Mel'nikov, M.E., Pletnev, S.P., Sedysheva, T.E., Punina, T.A., and Khudik, V.D., 2012. New data on the structure of the sedimentary section on the Ita Mai Tai Guyot (Magellan Seamounts, Pacific Ocean). Russian Journal of Pacific Geology, 6: 217–229.

[24]	Müller, R.D., Sdrolias, M., Gaina, C., and Roest, W.R., 2008. Age, spreading rates, and spreading asymmetry of the world's ocean crust. Geochemistry, Geophysics, Geosystems, 9: Q04006.

[25]

Müller, R.D., Flament, N., Cannon, J., Tetley, M.G., Williams, S.E., Cao, X., Bodur, Ö.F., Zahirovic, S., and Merdith, A., 2022. A tectonic-rules-based mantle reference frame since 1 billion years ago–Implications for supercontinent cycles and plate–mantle system evolution. Solid Earth, 13: 1127–1159.

[26]	Nakanishi, M., Tamaki, K., and Kobayashi, K., 1989. Mesozoic magnetic anomaly lineations and seafloor spreading history of the northwestern Pacific. Journal of Geophysical Research: Solid Earth, 94: 15437–15462.

[27]	Pan, J., Zhang, J., and Liu, S., 2002. Rasearch on the age of cobalt-rich crusts in western Pacific. Geological Review, 48(5): 460–467 (in Chinese with English abstract).

[28]	Puteanus, D., and Halbach, P., 1988. Correlation of Co concentration and growth rate: A method for age determination of ferromanganese crusts. Chemical Geology, 69: 73–85.

[29]	Qi, J., Wu, Z., Zhang, X., Wen, Z., Meng, X., Shang, L., Huo, F., and Hu, G., 2020. Deep seismic evidence of Cenozoic tectonic migration in the western Pacific back-arc area. Earth Science, 45(7): 2495–2507 (in Chinese with English abstract).

[30]	Ren, J.B., He, G.W., Yao, H.Q., Zhang, H., Yang, S.X., Deng, X.G., and Zhu, K.C., 2016. Geochemistry and significance of REE and PGE of the cobalt-rich crusts from West Pacific Ocean seamounts. Earth Science, 41(10): 1745–1757 (in Chinese with English abstract).

[31]	Ren, J.B., He, G.W., Yao, H.Q., Deng, X.G., Zhu, K.C., and Yang, S.X., 2017. The effects of phosphatization on the REY of Co-rich Fe-Mn crusts. Marine Geology & Quaternary Geology, 37: 33–43 (in Chinese with English abstract).

[32]

Ren, J.B., Yao, H.Q., Yang, Y., Wang, L., He, G.W., Lai, P.X., Zhou, J., Deng, X.G., Liu, S.J., Deng, X.Z., and Jiang, Y.H., 2023. Critical metal enrichment in atypical hydrogenetic ferromanganese nodules: A case study in the Central Basin Ridge of the West Philippine Basin. Chemical Geology, 615: 121224.

[33]	Ren, J.B., He, G.W., Yang, Y., Yu, M., Deng, Y.N., Pang, Y.T., Zhao, B., and Yao, H.Q., 2024. Ultraselective enrichment of trace elements in seawater by Co-rich ferromanganese nodules. Global and Planetary Change, 239: 104498.

[34]	Staudigel, H., and Clague, D., 2010. The Geological history of deep-sea volcanoes: Biosphere, hydrosphere, and lithosphere interactions. Oceanography, 23: 58–71.

[35]	Staudigel, H., Park, K.H., Pringle, M., Rubenstone, J.L., Smith, W.H.F., and Zindler, A., 1991. The longevity of the South Pacific isotopic and thermal anomaly. Earth and Planetary Science Letters, 102: 24–44.

[36]	Sun, X., Xue, T., He, G., Zhang, M., Shi, G., Wang, S., and Lu, F., 2006. Platinum group elements (PGE) and Os isotopic geochemistry of ferromanganese crusts from Pacific Ocean seamounts and their constraints on genesis. Acta Petrologica Sinica, 22: 3014–3026 (in Chinese with English abstract).

[37]	Suo, Y., Li, S., Cao, X., Li, X., Liu, X., and Cao, H., 2017. Mesozoic–Cenozoic inversion tectonics of East China and its implications for the subduction process of the oceanic plate. Earth Science Frontier, 24(4): 249–267 (in Chinese with English abstract).

[38]	Wang, Y., and Fang, N., 2020. Variation in growth rate of polymetallic crusts in the central and western Pacific Ocean and its constraining factors. Marine Geology & Quaternary Geology, 40(4): 162–174 (in Chinese with English abstract).

[39]	Wedgeworth, B., and Kellogg, J., 2013. A 3-D gravity-tectonic study of Ita Mai Tai Guyot: An uncompensated seamount in the east Mariana basin. In: Keating, B.H., Fryer, P., Batiza, R., Boehlert, G.W. (eds.), Geophysical Monograph Series. American Geophysical Union, Washington, D. C., 73–84.

[40]	Wei, H., Chu, H., Xu, J., Li, D., Feng, Y., and Zhang, G., 2023. Microthermometry and synchrotron radiation X-ray fluorescence analysis of fluid inclusions in the dongping gold deposit, northern margin of the North China Craton. Acta Geologica Sinica (English Edition), 97: 501–512.

[41]	Wu, G., Pulyaeva A., Liu, J., Li, X., and Li, X., 2011. Biostratigraphic research on the seamount ferromanganese crusts of the mid-Pacific Ocean. Acta Oceanologica Sinica, 33(4): 129–139 (in Chinese with English abstract).

[42]	Xu, Z., and Zheng, Y., 2019. Crust–mantle interaction in the paleo-Pacific subduction zone: Geochemical evidence from Cenozoic continental basalts in eastern China. Earth Science, 44(12): 4135–4143 (in Chinese with English abstract).

[43]	Yamazaki, T., 1993. A re-evaluation of cobalt-rich crust abundance on the Pacific Seamounts. International Journal of Offshore and Polar Engineering, 3(4): 258–263.

[44]	Yang, K., Ma, W., Zhang, W., Li, Z., He, G., Li, X., Qiu, Z., Wang, H., Zhao, B., Yang, Y., Wei, Z., and Liu, Y., 2023. Geological and geochemical characteristics of shallow-buried ferromanganese crusts from Weijia Guyot and their resource potential. Marine Geology, 464(5): 107119.

[45]	Zhang, H., Han, B., Lei, J., Zhao, J., and Yu, P., 2014. Calcareous nannofossil biostratigraphy and growth periods of Co-rich crusts from Pacific seamounts. Earth Science, 39(7): 775–783. (in Chinese with English abstract).

[46]	Zhao, B., Wei, Z.Q., Yang, Y., He, G.W., Zhang, H., and Ma, W.L., 2020a. Sedimentary characteristics and the implications of cobalt-rich crusts resources at Caiwei Guyot in the Western Pacific Ocean. Marine Georesources & Geotechnology, 38(9): 1037–1045.

[47]

Zhao, B., Yang, Y., Zhang, X.Y., He, G.W., Lü, W.C., Liu, Y.P., Wei, Z.Q., Deng, Y.N., and Huang, N., 2020b. Sedimentary characteristics based on sub-bottom profiling and the implications for mineralization of cobalt-rich ferromanganese crusts at Weijia Guyot, Western Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers, 158: 103223.

[48]	Zhao, B., Lü, W.C., He, G.W., Zhang, B.J., Wei, Z.Q., and Ning, Z.J., 2022. Sedimentary processes of Weijia Guyot and implications for western Pacific seamount evolution. Earth Science, 47(1): 357–367 (in Chinese with English abstract).

[49]	Zhao, L., Jin, X., and Gao, J., 2010. The effective elastic thickness of lithosphere in the mid-west Pacific and its geological significance. Earth Science, 35(4): 135–142 (in Chinese with English abstract).