Three distinct Holocene intervals of stalagmite deposition and nondeposition revealed in NW Madagascar, and their paleoclimate implications

Ny Riavo Gilbertinie Voarintsoa,Marie Olga Madison Razanatseheno,George Albert Brook,Lixin Wang,Gayatri Kathayat,Loren Bruce Railsback,Xianglei Li,Hai Cheng,Richard Lawrence Edwards,Amos Fety Michel Rakotondrazafy

doi:10.5194/cp-13-1771-2017

Abstract

Abstract. Petrographic features, mineralogy, and stable isotopes from two stalagmites, ANJB-2 and MAJ-5, respectively from Anjohibe and Anjokipoty caves, allow distinction of three intervals of the Holocene in NW Madagascar. The Malagasy early Holocene (between ca. 9.8 and 7.8 ka) and late Holocene (after ca. 1.6 ka) intervals (MEHI and MLHI, respectively) record evidence of stalagmite deposition. The Malagasy middle Holocene interval (MMHI, between ca. 7.8 and 1.6 ka) is marked by a depositional hiatus of ca. 6500 years. Deposition of these stalagmites indicates that the two caves were sufficiently supplied with water to allow stalagmite formation. This suggests that the MEHI and MLHI intervals may have been comparatively wet in NW Madagascar. In contrast, the long-term depositional hiatus during the MMHI implies it was relatively drier than the MEHI and the MLHI. The alternating wet–dry–wet conditions during the Holocene may have been linked to the long-term migrations of the Intertropical Convergence Zone (ITCZ). When the ITCZ's mean position is farther south, NW Madagascar experiences wetter conditions, such as during the MEHI and MLHI, and when it moves north, NW Madagascar climate becomes drier, such as during the MMHI. A similar wet–dry–wet succession during the Holocene has been reported in neighboring locations, such as southeastern Africa. Beyond these three subdivisions, the records also suggest wet conditions around the cold 8.2 ka event, suggesting a causal relationship. However, additional Southern Hemisphere high-resolution data will be needed to confirm this.

Highlights

Much is known about Holocene climate change worldwide (Mayewski et al, 2004; Wanner and Ritz, 2011; Wanner et al, 2011, 2015), high-resolution climate data for the Holocene period is still regionally limited in the Southern Hemisphere (SH) (e.g., Wanner et al, 2008, 2015; Marcott et al, 2013), including Madagascar
The timing of stalagmite deposition during the Malagasy early Holocene interval (MEHI) and the Malagasy late Holocene interval (MLHI) in NW Madagascar could be attributed to a more southward migration and/or an expanded Intertropical Convergence Zone (ITCZ), increasing the duration of the summer rainy seasons, perhaps linked to a stronger Malagasy monsoon. This could have been tied to the temperature gradient between the two hemispheres and weakening of the AMOC
The ca. 6500-year depositional hiatus during the Malagasy mid-Holocene interval (MMHI) could indicate a northward migration of the ITCZ, leading to relatively drier conditions in NW Madagascar

Summary

Introduction

Much is known about Holocene climate change worldwide (Mayewski et al, 2004; Wanner and Ritz, 2011; Wanner et al, 2011, 2015), high-resolution climate data for the Holocene period is still regionally limited in the Southern Hemisphere (SH) (e.g., Wanner et al, 2008, 2015; Marcott et al, 2013), including Madagascar. This uneven distribution of data hinders our understanding of the spatiotemporal characteristics of Holocene climate change and the forcings involved. New records from Madagascar could fill gaps in paleoclimate datasets for the SH that might help refine paleoclimate simulations, and provide a better understanding of global circulation and land–atmosphere–ocean interactions during the Holocene

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Discussion

Conclusion