Triple oxygen isotope reveals insolation-forced tropical moisture cycles

Lijuan Sha; Haowen Dang; Yue Wang; Jasper A. Wassenburg; Jonathan L. Baker; Hanying Li; Ashish Sinha; Yassine Ait Brahim; Nanping Wu; Zhengyao Lu; Ce Yang; Xiyu Dong; Jiayu Lu; Haiwei Zhang; Sasadhar Mahata; Yanjun Cai; Zhimin Jian; Hai Cheng

doi:10.1126/sciadv.adp7855

Triple oxygen isotope reveals insolation-forced tropical moisture cycles

Lijuan Sha, Haowen Dang, Yue Wang, Jasper A. Wassenburg, Jonathan L. Baker, Hanying Li, Ashish Sinha, Yassine Ait Brahim, Nanping Wu, Zhengyao Lu, Ce Yang, Xiyu Dong, Jiayu Lu, Haiwei Zhang, Sasadhar Mahata, Yanjun Cai, Zhimin Jian, Hai Cheng

MERGE: ModElling the Regional and Global Earth system

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

Abstract

Tropical oceans are the main global water vapor and latent heat sources, but their responses to radiative forcing remain unclear. Here, we investigate oceanic moisture dynamics of the western tropical Pacific (WTP) over the past 210,000 years through an approach of planktonic foraminiferal triple oxygen isotope (Δ′¹⁷O). The Δ′¹⁷O record is dominated by the precession cycles (~23,000 years), with lower values reflecting higher humidity in concert with higher Northern Hemisphere summer insolation. Our empirical and modeling results, combined with other geological archives, suggest that the enhanced moisture convergence over the WTP largely intensifies changes in the meridional and zonal hydrological cycles, affecting rainfall patterns in East Asia and northern South America. We propose that the insolation-driven WTP moisture dynamics play a pivotal role in regulating tropical hydroclimate.

Original language	English
Article number	eadp7855
Journal	Science Advances
Volume	10
Issue number	37
DOIs	https://doi.org/10.1126/sciadv.adp7855
Publication status	Published - 2024 Sept

Subject classification (UKÄ)

Earth and Related Environmental Sciences

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10.1126/sciadv.adp7855

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title = "Triple oxygen isotope reveals insolation-forced tropical moisture cycles",

abstract = "Tropical oceans are the main global water vapor and latent heat sources, but their responses to radiative forcing remain unclear. Here, we investigate oceanic moisture dynamics of the western tropical Pacific (WTP) over the past 210,000 years through an approach of planktonic foraminiferal triple oxygen isotope (Δ′17O). The Δ′17O record is dominated by the precession cycles (\textasciitilde{}23,000 years), with lower values reflecting higher humidity in concert with higher Northern Hemisphere summer insolation. Our empirical and modeling results, combined with other geological archives, suggest that the enhanced moisture convergence over the WTP largely intensifies changes in the meridional and zonal hydrological cycles, affecting rainfall patterns in East Asia and northern South America. We propose that the insolation-driven WTP moisture dynamics play a pivotal role in regulating tropical hydroclimate.",

author = "Lijuan Sha and Haowen Dang and Yue Wang and Wassenburg, \{Jasper A.\} and Baker, \{Jonathan L.\} and Hanying Li and Ashish Sinha and Brahim, \{Yassine Ait\} and Nanping Wu and Zhengyao Lu and Ce Yang and Xiyu Dong and Jiayu Lu and Haiwei Zhang and Sasadhar Mahata and Yanjun Cai and Zhimin Jian and Hai Cheng",

year = "2024",

month = sep,

doi = "10.1126/sciadv.adp7855",

language = "English",

volume = "10",

journal = "Science Advances",

issn = "2375-2548",

publisher = "American Association for the Advancement of Science (AAAS)",

number = "37",

}

TY - JOUR

T1 - Triple oxygen isotope reveals insolation-forced tropical moisture cycles

AU - Sha, Lijuan

AU - Dang, Haowen

AU - Wang, Yue

AU - Wassenburg, Jasper A.

AU - Baker, Jonathan L.

AU - Li, Hanying

AU - Sinha, Ashish

AU - Brahim, Yassine Ait

AU - Wu, Nanping

AU - Lu, Zhengyao

AU - Yang, Ce

AU - Dong, Xiyu

AU - Lu, Jiayu

AU - Zhang, Haiwei

AU - Mahata, Sasadhar

AU - Cai, Yanjun

AU - Jian, Zhimin

AU - Cheng, Hai

PY - 2024/9

Y1 - 2024/9

N2 - Tropical oceans are the main global water vapor and latent heat sources, but their responses to radiative forcing remain unclear. Here, we investigate oceanic moisture dynamics of the western tropical Pacific (WTP) over the past 210,000 years through an approach of planktonic foraminiferal triple oxygen isotope (Δ′17O). The Δ′17O record is dominated by the precession cycles (~23,000 years), with lower values reflecting higher humidity in concert with higher Northern Hemisphere summer insolation. Our empirical and modeling results, combined with other geological archives, suggest that the enhanced moisture convergence over the WTP largely intensifies changes in the meridional and zonal hydrological cycles, affecting rainfall patterns in East Asia and northern South America. We propose that the insolation-driven WTP moisture dynamics play a pivotal role in regulating tropical hydroclimate.

AB - Tropical oceans are the main global water vapor and latent heat sources, but their responses to radiative forcing remain unclear. Here, we investigate oceanic moisture dynamics of the western tropical Pacific (WTP) over the past 210,000 years through an approach of planktonic foraminiferal triple oxygen isotope (Δ′17O). The Δ′17O record is dominated by the precession cycles (~23,000 years), with lower values reflecting higher humidity in concert with higher Northern Hemisphere summer insolation. Our empirical and modeling results, combined with other geological archives, suggest that the enhanced moisture convergence over the WTP largely intensifies changes in the meridional and zonal hydrological cycles, affecting rainfall patterns in East Asia and northern South America. We propose that the insolation-driven WTP moisture dynamics play a pivotal role in regulating tropical hydroclimate.

UR - https://www.scopus.com/pages/publications/85204167567

U2 - 10.1126/sciadv.adp7855

DO - 10.1126/sciadv.adp7855

M3 - Article

C2 - 39259794

AN - SCOPUS:85204167567

SN - 2375-2548

VL - 10

JO - Science Advances

JF - Science Advances

IS - 37

M1 - eadp7855

ER -

Triple oxygen isotope reveals insolation-forced tropical moisture cycles

Abstract

Subject classification (UKÄ)

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