Environmental and trilobite diversity changes during the middle-late Cambrian SPICE event

Research output: Contribution to journalJournal articleResearchpeer-review

Standard

Environmental and trilobite diversity changes during the middle-late Cambrian SPICE event. / Zhang, Lei; Algeo, Thomas J.; Zhao, Laishi; Dahl, Tais W.; Chen, Zhong Qiang; Zhang, Zihu; Poulton, Simon W.; Hughes, Nigel C.; Gou, Xueqing; Li, Chao.

In: Geological Society of America. Bulletin, Vol. 136, No. 1-2, 2024, p. 810-828.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Zhang, L, Algeo, TJ, Zhao, L, Dahl, TW, Chen, ZQ, Zhang, Z, Poulton, SW, Hughes, NC, Gou, X & Li, C 2024, 'Environmental and trilobite diversity changes during the middle-late Cambrian SPICE event', Geological Society of America. Bulletin, vol. 136, no. 1-2, pp. 810-828. https://doi.org/10.1130/B36421.1

APA

Zhang, L., Algeo, T. J., Zhao, L., Dahl, T. W., Chen, Z. Q., Zhang, Z., Poulton, S. W., Hughes, N. C., Gou, X., & Li, C. (2024). Environmental and trilobite diversity changes during the middle-late Cambrian SPICE event. Geological Society of America. Bulletin, 136(1-2), 810-828. https://doi.org/10.1130/B36421.1

Vancouver

Zhang L, Algeo TJ, Zhao L, Dahl TW, Chen ZQ, Zhang Z et al. Environmental and trilobite diversity changes during the middle-late Cambrian SPICE event. Geological Society of America. Bulletin. 2024;136(1-2):810-828. https://doi.org/10.1130/B36421.1

Author

Zhang, Lei ; Algeo, Thomas J. ; Zhao, Laishi ; Dahl, Tais W. ; Chen, Zhong Qiang ; Zhang, Zihu ; Poulton, Simon W. ; Hughes, Nigel C. ; Gou, Xueqing ; Li, Chao. / Environmental and trilobite diversity changes during the middle-late Cambrian SPICE event. In: Geological Society of America. Bulletin. 2024 ; Vol. 136, No. 1-2. pp. 810-828.

Bibtex

@article{9b4fb8b952514f2786d79161d81f411f,
title = "Environmental and trilobite diversity changes during the middle-late Cambrian SPICE event",
abstract = "The Steptoean Positive Carbon Isotope Excursion (SPICE) event at ca. 497-494 Ma was a major carbon-cycle perturbation of the late Cambrian that coincided with rapid diversity changes among trilobites. Several scenarios (e.g., climatic/oceanic cooling and seawater anoxia) have been proposed to account for an extinction of trilobites at the onset of SPICE, but the exact mechanism remains unclear. Here, we present a chemostratigraphic study of carbonate carbon and carbonate-associated sulfate sulfur isotopes (813Ccarb and 834SCAS) and elemental redox proxies (UEF, MoEF, and Corg/P), augmented by secular trilobite diversity data, from both upper slope (Wangcun) and lower slope (Duibian) successions from the Jiangnan Slope, South China, spanning the Drumian to lower Jiangshanian. Redox data indicate locally/regionally well-oxygenated conditions throughout the SPICE event in both study sections except for low-oxygen (hypoxic) conditions within the rising limb of the SPICE (early-middle Paibian) at Duibian. As in coeval sections globally, the reported δ13Ccarb and δ34SCAS profiles exhibit firstorder coupling throughout the SPICE event, reflecting co-burial of organic matter and pyrite controlled by globally integrated marine productivity, organic preservation rates, and shelf hypoxia. Increasing δ34SCAS in the “Early SPICE” interval (late Guzhangian) suggests that significant environmental change (e.g., global-oceanic hypoxia) was under way before the global carbon cycle was markedly affected. Assessment of trilobite range data within a high-resolution biostratigraphic framework for the middle-late Cambrian facilitated reevaluation of the relationship of the SPICE to contemporaneous biodiversity changes. Trilobite diversity in South China declined during the Early SPICE (corresponding to the End-Marjuman Biomere Extinction, or EMBE, of Laurentia) and at the termination of the SPICE (corresponding to the End-Steptoean Biomere Extinction, or ESBE, of Laurentia), consistent with biotic patterns from other cratons. We infer that oxygen minimum zone and/or shelf hypoxia expanded as a result of locally enhanced productivity due to intensified upwelling following climatic cooling, and that expanded hypoxia played a major role in the EMBE at the onset of SPICE. During the SPICE event, global-ocean ventilation promoted marine biotic recovery, but termination of SPICE-related cooling in the late Paibian may have reduced global-ocean circulation, triggering further redox changes that precipitated the ESBE. Major changes in both marine environmental conditions and trilobite diversity during the late Guzhangian demonstrate that the SPICE event began earlier than the Guzhangian-Paibian boundary, as previously proposed.",
author = "Lei Zhang and Algeo, {Thomas J.} and Laishi Zhao and Dahl, {Tais W.} and Chen, {Zhong Qiang} and Zihu Zhang and Poulton, {Simon W.} and Hughes, {Nigel C.} and Xueqing Gou and Chao Li",
note = "Publisher Copyright: {\textcopyright} 2024 Geological Society of America. All Rights Reserved.",
year = "2024",
doi = "10.1130/B36421.1",
language = "English",
volume = "136",
pages = "810--828",
journal = "Geological Society of America. Bulletin",
issn = "0016-7606",
publisher = "The Geological Society of America",
number = "1-2",

}

RIS

TY - JOUR

T1 - Environmental and trilobite diversity changes during the middle-late Cambrian SPICE event

AU - Zhang, Lei

AU - Algeo, Thomas J.

AU - Zhao, Laishi

AU - Dahl, Tais W.

AU - Chen, Zhong Qiang

AU - Zhang, Zihu

AU - Poulton, Simon W.

AU - Hughes, Nigel C.

AU - Gou, Xueqing

AU - Li, Chao

N1 - Publisher Copyright: © 2024 Geological Society of America. All Rights Reserved.

PY - 2024

Y1 - 2024

N2 - The Steptoean Positive Carbon Isotope Excursion (SPICE) event at ca. 497-494 Ma was a major carbon-cycle perturbation of the late Cambrian that coincided with rapid diversity changes among trilobites. Several scenarios (e.g., climatic/oceanic cooling and seawater anoxia) have been proposed to account for an extinction of trilobites at the onset of SPICE, but the exact mechanism remains unclear. Here, we present a chemostratigraphic study of carbonate carbon and carbonate-associated sulfate sulfur isotopes (813Ccarb and 834SCAS) and elemental redox proxies (UEF, MoEF, and Corg/P), augmented by secular trilobite diversity data, from both upper slope (Wangcun) and lower slope (Duibian) successions from the Jiangnan Slope, South China, spanning the Drumian to lower Jiangshanian. Redox data indicate locally/regionally well-oxygenated conditions throughout the SPICE event in both study sections except for low-oxygen (hypoxic) conditions within the rising limb of the SPICE (early-middle Paibian) at Duibian. As in coeval sections globally, the reported δ13Ccarb and δ34SCAS profiles exhibit firstorder coupling throughout the SPICE event, reflecting co-burial of organic matter and pyrite controlled by globally integrated marine productivity, organic preservation rates, and shelf hypoxia. Increasing δ34SCAS in the “Early SPICE” interval (late Guzhangian) suggests that significant environmental change (e.g., global-oceanic hypoxia) was under way before the global carbon cycle was markedly affected. Assessment of trilobite range data within a high-resolution biostratigraphic framework for the middle-late Cambrian facilitated reevaluation of the relationship of the SPICE to contemporaneous biodiversity changes. Trilobite diversity in South China declined during the Early SPICE (corresponding to the End-Marjuman Biomere Extinction, or EMBE, of Laurentia) and at the termination of the SPICE (corresponding to the End-Steptoean Biomere Extinction, or ESBE, of Laurentia), consistent with biotic patterns from other cratons. We infer that oxygen minimum zone and/or shelf hypoxia expanded as a result of locally enhanced productivity due to intensified upwelling following climatic cooling, and that expanded hypoxia played a major role in the EMBE at the onset of SPICE. During the SPICE event, global-ocean ventilation promoted marine biotic recovery, but termination of SPICE-related cooling in the late Paibian may have reduced global-ocean circulation, triggering further redox changes that precipitated the ESBE. Major changes in both marine environmental conditions and trilobite diversity during the late Guzhangian demonstrate that the SPICE event began earlier than the Guzhangian-Paibian boundary, as previously proposed.

AB - The Steptoean Positive Carbon Isotope Excursion (SPICE) event at ca. 497-494 Ma was a major carbon-cycle perturbation of the late Cambrian that coincided with rapid diversity changes among trilobites. Several scenarios (e.g., climatic/oceanic cooling and seawater anoxia) have been proposed to account for an extinction of trilobites at the onset of SPICE, but the exact mechanism remains unclear. Here, we present a chemostratigraphic study of carbonate carbon and carbonate-associated sulfate sulfur isotopes (813Ccarb and 834SCAS) and elemental redox proxies (UEF, MoEF, and Corg/P), augmented by secular trilobite diversity data, from both upper slope (Wangcun) and lower slope (Duibian) successions from the Jiangnan Slope, South China, spanning the Drumian to lower Jiangshanian. Redox data indicate locally/regionally well-oxygenated conditions throughout the SPICE event in both study sections except for low-oxygen (hypoxic) conditions within the rising limb of the SPICE (early-middle Paibian) at Duibian. As in coeval sections globally, the reported δ13Ccarb and δ34SCAS profiles exhibit firstorder coupling throughout the SPICE event, reflecting co-burial of organic matter and pyrite controlled by globally integrated marine productivity, organic preservation rates, and shelf hypoxia. Increasing δ34SCAS in the “Early SPICE” interval (late Guzhangian) suggests that significant environmental change (e.g., global-oceanic hypoxia) was under way before the global carbon cycle was markedly affected. Assessment of trilobite range data within a high-resolution biostratigraphic framework for the middle-late Cambrian facilitated reevaluation of the relationship of the SPICE to contemporaneous biodiversity changes. Trilobite diversity in South China declined during the Early SPICE (corresponding to the End-Marjuman Biomere Extinction, or EMBE, of Laurentia) and at the termination of the SPICE (corresponding to the End-Steptoean Biomere Extinction, or ESBE, of Laurentia), consistent with biotic patterns from other cratons. We infer that oxygen minimum zone and/or shelf hypoxia expanded as a result of locally enhanced productivity due to intensified upwelling following climatic cooling, and that expanded hypoxia played a major role in the EMBE at the onset of SPICE. During the SPICE event, global-ocean ventilation promoted marine biotic recovery, but termination of SPICE-related cooling in the late Paibian may have reduced global-ocean circulation, triggering further redox changes that precipitated the ESBE. Major changes in both marine environmental conditions and trilobite diversity during the late Guzhangian demonstrate that the SPICE event began earlier than the Guzhangian-Paibian boundary, as previously proposed.

U2 - 10.1130/B36421.1

DO - 10.1130/B36421.1

M3 - Journal article

AN - SCOPUS:85183138039

VL - 136

SP - 810

EP - 828

JO - Geological Society of America. Bulletin

JF - Geological Society of America. Bulletin

SN - 0016-7606

IS - 1-2

ER -

ID: 384568778