doi:10.11932/karst20240201

410 ka weak monsoon event recorded by stalagmites in Jinfo Cave of Chongqing

doi: 10.11932/karst20240201

XU Yibin^1
,,
YANG Xunlin^{1, 2, 3},
YUAN Daoxian^{1, 2, 4},
HU Mingguang¹,
GE Xiaoyan¹,
GONG Meng¹

1.
School of Geographical Sciences, Southwest University/National Observation and Research Station of Karst Ecosystem in Jinfo Mountain of Chongqing, Chongqing 400715, China
2.
Chongqing Key Laboratory of karst Environment, Chongqing 400715, China
3.
Chongqing Nanchuan Field Base of Karst Ecological Environment, Ministry of Natural Resources, Chongqing 400715, China
4.
Institute of Karst Geology, CAGS/Key Laboratory of Karst Dynamics, MNR & GZAR, Guilin, Guangxi 541004, China

摘要

Abstract: The freshwater discharge from melting ice sheets in the deglaciation or glaciation is prone to anomalies in ocean−atmosphere transport between different latitudes, which can lead to a series of abrupt millennial-scale climate events, either obvious or not, such as the Younger Dryas (YD) events and YD-like events. Marine Isotope Stage 11c (MIS 11c) serves as one of the best references for the current Holocene, and the studies of possible YD-like events and their triggering mechanisms during Holocene are conducive to the understanding of the occurrence pattern of extreme climate events. In this paper, the results of the study on the J33 δ¹⁸O sequence records of stalagmites in Jinfo Cave, Chongqing, are shown: (1) Stalagmites in the Asian monsoon climate zone reveal a millennial-scale weak monsoon event that occurred around 410 ka BP prior to the Glacial Maximum of MIS 11 interglacial period. (2) Both the 410 ka weak monsoon event and the YD event occurred during the gradual strengthening of the monsoon and ascending branch of summer insolation in the Northern Hemisphere prior to the Glacial Maximum of interglacial period. This was also a time when Atlantic Meridional Overturning Circulation (AMOC) disturbance occurred. The duration, internal structure, and pattern of the events were similar, with differences in the change magnitude and ice volume conditions. (3) The weak monsoon event that occurred in 410 ka BP was primarily influenced by the combined effects of insolation and AMOC. This event was characterized by a sustained warming process that accelerated the melting of the Greenland ice sheet, leading to the destabilization of this ice sheet. The continuous flowing of freshwater into the North Atlantic resulted in a short-lived AMOC oscillation. The weakening of the AMOC resulted in a cold anomaly over the North Atlantic. As a result of atmospheric telecorrelation, the weaker AMOC led to a weaker Asian Summer Monsoon (ASM)
- Asian Summer Monsoon /
- MIS 11c /
- stalagmite δ¹⁸O /
- weak monsoon event /
- Jinfo Cave /
- Southwest China

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Figure 1. Location of Jinfo Cave

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Figure 2. Profile of the stalagmite J33 (A) and age model (B)

The ages of stalagmite J33 were obtained by linear interpolation, and the red error bars in the figure indicate ²³⁰Th ages and 2 σ errors.

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Figure 3. Comparison of δ¹⁸O values of stalagmite J33 in Jinfo Cave and of stalagmite SB14 in Sanbao cave

(A) δ¹⁸O record of stalagmite J33 and dating errors (in this study); (B) δ¹⁸O record of stalagmite SB14 and dating errors^[13]

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Figure 4. 410 ka BP weak monsoon event

(A) records of insolation (brown) and inclination (black) at 65 °N on July 21^[22]; (B) δ¹⁸O record of stalagmite J33 and dating error (in this study); (C) δ¹⁸O record of stalagmite SB14 and dating error^[14]; (D) record of temperature reconstruction for North Atlantic borehole M23414 0−200 m TEXL 86^[23]; (E) record of North Atlantic borehole ODP983% N. pachyderma(s)^[24]; (F) Magnetization rate-based record of wind-sand concentration in the central Red Sea^[21]; (G) records of Alkenone- and foraminifera-based sea surface temperature (green and light green) from North Atlantic borehole ODP958^[25] and records of alkenone-based sea surface temperature (red) from the Mid-Atlantic IODP U1313^[26]; (H) ODP980 benthic foraminiferal δ¹³C record^[27]; (I) ODP983 IRD record^[22]. Blue bars in the figure indicate weak monsoon events or cold events.

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Figure 5. Comparison between the 410 ka weak monsoon event and the YD event (Adapted from Zhang Riping^[38])

(A) Stalagmite J33 δ¹⁸O record (green, in this study) and insolation record at 65 °N on July 21^[22] (black); (B) record of stalagmite H82 δ¹⁸O in Hulu cave^[39-40] (pink), record of stalagmite D4 δ¹⁸O^[41] in Dongge cave (blue) and insolation record at 65 °N on July 21^[22] (red); (C) NGRIP δ¹⁸O record at AICC 2012 dating scale^[42] (green) and insolation record at 65 °N on July 21^[18] (red). (A) is shown by the time coordinate of upper horizontal axis, and (B) and (C) are shown by the time coordinate of lower horizontal axis. The blue bars in the figure indicate weak monsoon events; the yellow bars indicate strong monsoon events; and the black dotted lines respectively indicate the ending time of the beginning phase and the starting time of the ending phase of the event.

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Figure 6. Comparison of selected global records during the 410 ka weak monsoon event and the YD event

(A) records of insolation (brown) and inclination rate (black) at 65 °N on July 21^[22]; (B) precession records^[22]; (C) record of stalagmite J33 δ¹⁸O (turquoise on the left, in this study); δ¹⁸O record of stalagmite H82 in Hulu cave^[39-40] (pink on the right, ), δ¹⁸O record of stalagmite D4 in Dongge cave^[41] (dark blue); (D) δ¹³C record of ODP980 benthic foraminiferal^[26] (on the left); ²³¹Pa/²³⁰Th ratio of marine sediments^[48] (on the right); (E) records of Antarctic ice cores EDC CO₂ (gray) and CH₄ (blue)^[49]; (F) LR04 δ¹⁸O record^[50] and ODP983 IRD record^[24]. The blue bars in Figure six indicate weak monsoon events or cold events.

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Table 1. ²³⁰Th date results for stalagmite J33 (‘*’ indicates the new measured data.)

Sample Number	Depth (mm)	²³⁸U (ppb)	²³²Th (ppt)	²³⁰Th / ²³²Th (atomic×10⁻⁶)	δ²³⁴U (measured)	²³⁰Th / ²³⁸U (activity)	Age (ka BP) (uncorrected)	Age (ka BP) (corrected)	δ²³⁴U_Initial (corrected)
J33-1	144.9	2516.4±0.1	884.9±10.2	72003.1±832.5	424.5±0.3	1.536±0.001	393.5±2.0	393.5±2.0	1288.5±7.5
J33-2	185.7	2875.4±0.1	429.4±10.7	167329.4±4184.0	406.4±0.3	1.516±0.001	400.6±1.5	400.6±1.5	1258.9±5.3
J33-3	196.9	2158.7±0.1	2182.9±11.0	24635.3±127.0	402.8±0.3	1.511±0.002	400.9±3.2	400.9±3.2	1248.6±11.2
J33-4	230.9	3113.8±0.2	1397.6±9.8	55814.2±391.3	406.0±0.3	1.519±0.001	409.4±1.6	409.4±1.6	1288.8±5.9
J33-5	268.7	2791.5±0.2	738.7±28.7	95730.9±3715.6	416.4±0.3	1.536±0.001	415.6±1.6	415.6±1.6	1345.7±6.1
J33-6	301.2	2906.0±0.1	479.0±8.4	154689.1±2718.8	422.2±0.3	1.546±0.001	420.5±1.8	420.5±1.8	1383.2±7.1
J33-7*	306.0	3621.9±8.7	672.0±1.6	137821.0±39.0	425.2±0.3	1.551±0.000	421.1±1.3	421.1±1.3	1395.4±5.3
J33-8*	333.0	3173.3±7.7	607.6±1.5	134437.0±38.0	431.6±0.4	1.561±0.000	425.2±1.5	425.2±1.5	1432.7±6.2
U decay constants: λ₂₃₈ = 1.55125×10⁻¹⁰^[13] and λ₂₃₄ = 2.82206×10^−6[9]. Th decay constant: λ₂₃₀ = 9.1705×10^−6[11]. δ²³⁴U = ([²³⁴U/²³⁸U] _activity − 1) ×1000. δ²³⁴U_initial was calculated based on ²³⁰Th age (T), i.e., δ²³⁴U_initial = δ²³⁴U_measured×e^λ234×T. Corrected ²³⁰Th ages assume the initial ²³⁰Th/²³²Th atomic ratio of 4.4±2.2×10⁻⁶. Those are the values for a material at secular equilibrium, with the bulk earth ²³²Th/²³⁸U value of 3.8. The errors are arbitrarily assumed to be 50%. "BP" stands for "Before Present" where the "Present" is defined as the year 1950 CE.

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