Large-scale, astronomically paced sediment input to the North Sea Basin during the Paleocene Eocene Thermal Maximum

Simin Jin; David B. Kemp; David W. Jolley; Manuel Vieira; James C. Zachos; Chunju Huang; Mingsong Li; Wenhan Chen

doi:10.1016/j.epsl.2021.117340

Large-scale, astronomically paced sediment input to the North Sea Basin during the Paleocene Eocene Thermal Maximum

Simin Jin, David B. Kemp^* (Corresponding Author), David W. Jolley, Manuel Vieira, James C. Zachos, Chunju Huang, Mingsong Li, Wenhan Chen

^*Corresponding author for this work

Geology and Geophysics

Research output: Contribution to journal › Article › peer-review

18 Citations (Scopus)

Abstract

Among the predicted responses to ongoing climate warming is that coastal and inland areas may experience increasingly extreme weather, with potentially more droughts and floods. Such changes will have corresponding impacts on sedimentary systems. The Paleocene-Eocene thermal maximum (PETM, ∼56 Ma) was the most abrupt extreme warming event of the Cenozoic, and has historically been treated as a potentially useful analogue for understanding regional and global responses to future climate change. Emerging evidence indicates that the PETM significantly altered the hydrological cycle, but the precise response(s) of sedimentary systems to the large-scale hydroclimatic changes of the PETM are mostly unknown. Here, we present the thickest sedimentary archive yet recorded of the PETM from a cored well in the North Sea Basin, offshore UK. The negative carbon isotope excursion (CIE) marking the PETM in this succession spans 140.2 m, and is coeval with the occurrence of >200 turbidite sandstone beds. The CIE and these turbidites occur in an otherwise mud-dominated succession, and suggest an order of magnitude increase in sedimentation rates coeval with the PETM. Time series analysis of turbidite recurrence indicates a ∼21 kyr astronomical precession paced climate control on this large-scale sediment influx. A time lag between the onset of the CIE and a marked increase in turbidite deposition is also recognized. Our work uncovers a clear link between extreme climate warming, intensification of the hydrological cycle, and large-scale changes in sediment supply at the PETM. Moreover, our findings reveal the importance of astronomical climate forcing in mediating these factors over long, multi-millennial timescales.

Original language	English
Article number	117340
Number of pages	12
Journal	Earth and Planetary Science Letters
Volume	579
Early online date	21 Dec 2021
DOIs	https://doi.org/10.1016/j.epsl.2021.117340
Publication status	Published - 1 Feb 2022

Bibliographical note

Funding Information:
This work was supported by the National Natural Science Foundation of China (Grant No. 41888101 , 41772029 , 42172039 ), and the National Recruitment Program for Young Professionals (P.R. China) to DBK. We thank Shell UK and partners for their support and permission to publish this research. We also thank Jean-Philippe Avouac and Matthias Meier for providing code and helpful discussion. This work is a contribution to IGCP 739.

CRediT authorship contribution statement
Simin Jin: Devised methodology, data collection and curation, data analysis, writing of original draft, reviewing and editing
David B. Kemp: Supervision and project conceptualization, writing, reviewing and editing, funding acquisition
David W. Jolley: Provision of study materials and data, writing, reviewing and editing
Manuel Vieira: Provision of study materials, writing, reviewing and editing
James C. Zachos: Conceptualization, writing, reviewing and editing
Chunju Huang: Supervision, cyclostratigraphic data analysis
Mingsong Li: Methodology, cyclostratigraphic data analysis
Wenhan Chen: Data analysis, reviewing and editing

Keywords

astronomical cycles
carbon isotope excursion
hydrological cycle
North Sea Basin
PETM
turbidites

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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Cite this

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title = "Large-scale, astronomically paced sediment input to the North Sea Basin during the Paleocene Eocene Thermal Maximum",

abstract = "Among the predicted responses to ongoing climate warming is that coastal and inland areas may experience increasingly extreme weather, with potentially more droughts and floods. Such changes will have corresponding impacts on sedimentary systems. The Paleocene-Eocene thermal maximum (PETM, ∼56 Ma) was the most abrupt extreme warming event of the Cenozoic, and has historically been treated as a potentially useful analogue for understanding regional and global responses to future climate change. Emerging evidence indicates that the PETM significantly altered the hydrological cycle, but the precise response(s) of sedimentary systems to the large-scale hydroclimatic changes of the PETM are mostly unknown. Here, we present the thickest sedimentary archive yet recorded of the PETM from a cored well in the North Sea Basin, offshore UK. The negative carbon isotope excursion (CIE) marking the PETM in this succession spans 140.2 m, and is coeval with the occurrence of >200 turbidite sandstone beds. The CIE and these turbidites occur in an otherwise mud-dominated succession, and suggest an order of magnitude increase in sedimentation rates coeval with the PETM. Time series analysis of turbidite recurrence indicates a ∼21 kyr astronomical precession paced climate control on this large-scale sediment influx. A time lag between the onset of the CIE and a marked increase in turbidite deposition is also recognized. Our work uncovers a clear link between extreme climate warming, intensification of the hydrological cycle, and large-scale changes in sediment supply at the PETM. Moreover, our findings reveal the importance of astronomical climate forcing in mediating these factors over long, multi-millennial timescales.",

keywords = "astronomical cycles, carbon isotope excursion, hydrological cycle, North Sea Basin, PETM, turbidites",

author = "Simin Jin and Kemp, {David B.} and Jolley, {David W.} and Manuel Vieira and Zachos, {James C.} and Chunju Huang and Mingsong Li and Wenhan Chen",

note = "Funding Information: This work was supported by the National Natural Science Foundation of China (Grant No. 41888101 , 41772029 , 42172039 ), and the National Recruitment Program for Young Professionals (P.R. China) to DBK. We thank Shell UK and partners for their support and permission to publish this research. We also thank Jean-Philippe Avouac and Matthias Meier for providing code and helpful discussion. This work is a contribution to IGCP 739. CRediT authorship contribution statement Simin Jin: Devised methodology, data collection and curation, data analysis, writing of original draft, reviewing and editing David B. Kemp: Supervision and project conceptualization, writing, reviewing and editing, funding acquisition David W. Jolley: Provision of study materials and data, writing, reviewing and editing Manuel Vieira: Provision of study materials, writing, reviewing and editing James C. Zachos: Conceptualization, writing, reviewing and editing Chunju Huang: Supervision, cyclostratigraphic data analysis Mingsong Li: Methodology, cyclostratigraphic data analysis Wenhan Chen: Data analysis, reviewing and editing",

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AU - Jin, Simin

AU - Kemp, David B.

AU - Jolley, David W.

AU - Vieira, Manuel

AU - Zachos, James C.

AU - Huang, Chunju

AU - Li, Mingsong

AU - Chen, Wenhan

N1 - Funding Information: This work was supported by the National Natural Science Foundation of China (Grant No. 41888101 , 41772029 , 42172039 ), and the National Recruitment Program for Young Professionals (P.R. China) to DBK. We thank Shell UK and partners for their support and permission to publish this research. We also thank Jean-Philippe Avouac and Matthias Meier for providing code and helpful discussion. This work is a contribution to IGCP 739. CRediT authorship contribution statement Simin Jin: Devised methodology, data collection and curation, data analysis, writing of original draft, reviewing and editing David B. Kemp: Supervision and project conceptualization, writing, reviewing and editing, funding acquisition David W. Jolley: Provision of study materials and data, writing, reviewing and editing Manuel Vieira: Provision of study materials, writing, reviewing and editing James C. Zachos: Conceptualization, writing, reviewing and editing Chunju Huang: Supervision, cyclostratigraphic data analysis Mingsong Li: Methodology, cyclostratigraphic data analysis Wenhan Chen: Data analysis, reviewing and editing

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N2 - Among the predicted responses to ongoing climate warming is that coastal and inland areas may experience increasingly extreme weather, with potentially more droughts and floods. Such changes will have corresponding impacts on sedimentary systems. The Paleocene-Eocene thermal maximum (PETM, ∼56 Ma) was the most abrupt extreme warming event of the Cenozoic, and has historically been treated as a potentially useful analogue for understanding regional and global responses to future climate change. Emerging evidence indicates that the PETM significantly altered the hydrological cycle, but the precise response(s) of sedimentary systems to the large-scale hydroclimatic changes of the PETM are mostly unknown. Here, we present the thickest sedimentary archive yet recorded of the PETM from a cored well in the North Sea Basin, offshore UK. The negative carbon isotope excursion (CIE) marking the PETM in this succession spans 140.2 m, and is coeval with the occurrence of >200 turbidite sandstone beds. The CIE and these turbidites occur in an otherwise mud-dominated succession, and suggest an order of magnitude increase in sedimentation rates coeval with the PETM. Time series analysis of turbidite recurrence indicates a ∼21 kyr astronomical precession paced climate control on this large-scale sediment influx. A time lag between the onset of the CIE and a marked increase in turbidite deposition is also recognized. Our work uncovers a clear link between extreme climate warming, intensification of the hydrological cycle, and large-scale changes in sediment supply at the PETM. Moreover, our findings reveal the importance of astronomical climate forcing in mediating these factors over long, multi-millennial timescales.

AB - Among the predicted responses to ongoing climate warming is that coastal and inland areas may experience increasingly extreme weather, with potentially more droughts and floods. Such changes will have corresponding impacts on sedimentary systems. The Paleocene-Eocene thermal maximum (PETM, ∼56 Ma) was the most abrupt extreme warming event of the Cenozoic, and has historically been treated as a potentially useful analogue for understanding regional and global responses to future climate change. Emerging evidence indicates that the PETM significantly altered the hydrological cycle, but the precise response(s) of sedimentary systems to the large-scale hydroclimatic changes of the PETM are mostly unknown. Here, we present the thickest sedimentary archive yet recorded of the PETM from a cored well in the North Sea Basin, offshore UK. The negative carbon isotope excursion (CIE) marking the PETM in this succession spans 140.2 m, and is coeval with the occurrence of >200 turbidite sandstone beds. The CIE and these turbidites occur in an otherwise mud-dominated succession, and suggest an order of magnitude increase in sedimentation rates coeval with the PETM. Time series analysis of turbidite recurrence indicates a ∼21 kyr astronomical precession paced climate control on this large-scale sediment influx. A time lag between the onset of the CIE and a marked increase in turbidite deposition is also recognized. Our work uncovers a clear link between extreme climate warming, intensification of the hydrological cycle, and large-scale changes in sediment supply at the PETM. Moreover, our findings reveal the importance of astronomical climate forcing in mediating these factors over long, multi-millennial timescales.

KW - astronomical cycles

KW - carbon isotope excursion

KW - hydrological cycle

KW - North Sea Basin

KW - PETM

KW - turbidites

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SN - 0012-821X

VL - 579

JO - Earth and Planetary Science Letters

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M1 - 117340

ER -

Large-scale, astronomically paced sediment input to the North Sea Basin during the Paleocene Eocene Thermal Maximum

Abstract

Bibliographical note

Keywords

UN SDGs

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