Paleomagnetic investigation of the basal Maieberg Formation (Namibia) cap carbonate sequence (635 Ma): Implications for Snowball Earth postglacial dynamics

Thales Pescarini, Ricardo I.F. Trindade, Paul F. Hoffman, Lucy Gomes Sant’Anna
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Abstract

In this study, we investigate the paleomagnetism of the basal Maieberg Formation (Namibia) cap carbonate sequence to elucidate its magnetic properties and paleolatitude of deposition, establish global correlations, and contribute to the understanding of Snowball Earth postglacial dynamics. Two distinct magnetization components, C1 and C2, were identified. C1 is interpreted as a depositional or post-depositional remanent magnetization carried by detrital pseudo-single domain (PSD) magnetite, while the C2 component is a thermochemical remanent magnetization carried by fine authigenic single domain (SD)−PSD magnetite. The deposition paleolatitude provided by C1 is 33.3° ± 3.2°, which gives an initial quantitative approximation of the paleolatitude for the underlying Marinoan Ghaub diamictites. The thickness of the Keilberg Member cap dolostone is anomalously high for the paleolatitude calculated with C1, which suggests that other factors besides the influence of the paleolatitude on carbonate oversaturation may have influenced the sedimentary production of cap dolostones and the overall thickness of the flooding cap carbonate sequence. Possible explanations could include the influence of alkalinity input combined with local tectonic subsidence during a long glacial period with unusually low sedimentation rates, which appear to be in a favorable configuration for the substantial thickness of the Keilberg Member. Paleomagnetic field reversals at the Keilberg cap dolostone and analogous units globally suggest a longer duration of marine transgression than energy-balance deglaciation models and sedimentological-geochemical observations have constrained. Factors such as ocean warming, thermal expansion, and local glacio-isostatic adjustments imply extended marine transgressions beyond the deglaciation period. Still, magnetostratigraphic estimates for postglacial transgressive sequences require longer time scales by a factor of five or more. Thus, the conflict arising between estimates derived from paleomagnetic data and the constraints imposed by climate physics underscores uncertainties regarding an unconventional field state or a remanence acquisition mechanism within these cap carbonates that is not fully understood. Importantly, if such a phenomenon proves to be primary and global, the widespread occurrence of these stratigraphically compressed reversals would support the precise temporal correlation between Marinoan cap dolostones. The C2 pole correlates with Cambrian remagnetization poles observed in carbonates from West Gondwana, which now extend to the Congo craton. The remanence acquisition of C2 likely stems from diagenesis-related low-temperature authigenic magnetite formation after the conversion of iron-rich smectite to iron-poor illite. Cooling associated with the Kaoko orogen’s exhumation and tectonic uplift possibly locked the magnetic system at ca. 520 Ma, supported by the C2 pole position on the West Gondwana apparent polar wander path, although other explanations remain valid.
纳米比亚 Maieberg Formation 盖碳酸盐序列基底(635 Ma)的古地磁调查:对雪球地球冰川后动力学的影响
在这项研究中,我们调查了基底 Maieberg Formation(纳米比亚)盖碳酸盐序列的古地磁性,以阐明其磁性特征和沉积的古纬度,建立全球相关性,并促进对雪球地球冰期后动力学的理解。研究发现了两个不同的磁化成分,即 C1 和 C2。C1 被解释为由残积伪单域(PSD)磁铁矿携带的沉积或沉积后剩磁,而 C2 部分则是由细微自生单域(SD)-PSD 磁铁矿携带的热化学剩磁。C1 提供的沉积古纬度为 33.3° ± 3.2°,这给出了下伏马里诺期高布二长岩古纬度的初步定量近似值。根据 C1 计算出的古纬度,Keilberg 成员盖帽白云岩的厚度异常高,这表明除了古纬度对碳酸盐过饱和的影响外,其他因素也可能影响了盖帽白云岩的沉积生成和洪积盖帽碳酸盐序列的整体厚度。可能的解释包括:在沉积速率异常低的漫长冰川期,碱度输入与当地构造沉降相结合的影响,这似乎是基尔贝格成员厚度可观的有利构造。凯尔贝格盖白云岩和全球类似单元的古磁场反转表明,海洋横断的持续时间比能量平衡脱冰期模型和沉积地质化学观测所限制的时间更长。海洋变暖、热膨胀和局部冰川-等静力调整等因素意味着海洋跃迁的时间超过了降冰期。尽管如此,对冰川期后横断序列的磁地层学估算需要更长的时间尺度,长达五倍或更多。因此,根据古地磁数据得出的估算结果与气候物理学所施加的限制之间产生的冲突,凸显了这些盖层碳酸盐岩中的非常规场状态或剩磁获取机制的不确定性。重要的是,如果这种现象被证明是原生的和全球性的,那么这些地层压缩反转的广泛出现将支持马里诺盖白云岩之间精确的时间相关性。C2极点与在西冈瓦纳碳酸盐岩中观察到的寒武纪再磁化极点相关,目前该极点已延伸至刚果陨石坑。C2 的剩磁获得很可能源于富铁闪长岩转化为贫铁伊利石后形成的与成岩作用相关的低温自生磁铁矿。与Kaoko造山运动和构造抬升相关的冷却可能在约520 Ma时锁定了磁性系统。西冈瓦纳明显极地漫游路径上的 C2 极位置支持了 520 Ma 的磁系统,尽管其他解释仍然有效。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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