A. Erbello, C. Colleps, D. Melnick, E. R. Sobel, B. Bookhagen, H. Pingel, G. Zeilinger, P. van der Beek, M. R. Strecker
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Single-grain AHe ages ranging from 1.0 to 136.8 Ma were recorded in 32 samples, and single-grain ZHe ages from three samples range between 142.2 and 335.6 Ma. The youngest AHe ages were obtained from the Chew Bahir Basin and the narrow deformation zone in the Gofa Province. Our thermal modeling results reflect little or no significant regional crustal cooling prior to extensive volcanism, which started at about 45 Ma. Conversely, new and previously published thermal history models suggest that widespread crustal cooling related to regional extension occurred between ∼27 and 20 Ma. Thermal modeling results from subsets of samples indicate that following this initial diffuse extensional deformation, renewed exhumation occurred along a narrow zone within the Gofa Province and the Chew Bahir Basin during the middle to late Miocene (15-6 Ma) and Pliocene (<5 Ma), respectively. The crustal cooling phases follow a regional trend in volcanic episodes. For example, initial cooling between 27 and 20 Ma corresponds with the end of widespread flood-basalt volcanism (45–28 Ma), suggesting that spatially diffuse normal faulting may have initiated shortly after the emplacement of voluminous and areally extensive flood basalts. The Miocene and Pliocene shifts in deformation along the Mali-Dancha and Bala-Kela basins in the Gofa Province and the Chew Bahir Basin, respectively, may indicate strain localization during the late stage of rifting and ongoing tectonic interaction between the sMER and the nKR. 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引用次数: 0
摘要
埃塞俄比亚主断裂带(sMER)南部和肯尼亚断裂带(nKR)北部之间宽断裂带(BRZ)上的戈法省(Gofa Province)和楚巴希尔盆地(Chew Bahir Basin)记录了东非早期的火山活动和相关断层活动;然而,火山活动和断层活动之间的时空关系仍然没有得到很好的解释。我们应用磷灰石(U-Th)/He(AHe)和锆石(U-Th)/He(ZHe)热时测定法对来自延伸戈法省(Gofa Province)和楚巴希尔盆地(Chew Bahir Basin)出露的底壁岩块的新元古代基底岩石进行了测定,并结合肯尼亚断裂带(BRZ)中年代明确的区域火山岩单元对测定结果进行了分析,以揭示构造出露、断层和火山活动之间的相互作用。32个样品的单粒AHe年龄介于1.0至136.8Ma之间,3个样品的单粒ZHe年龄介于142.2至335.6Ma之间。最年轻的 AHe 年龄来自 Chew Bahir 盆地和戈法省的狭窄变形带。我们的热建模结果表明,在大约 45 Ma 开始的大范围火山活动之前,区域地壳几乎没有明显的冷却。相反,新的和以前公布的热历史模型表明,与区域延伸有关的大范围地壳冷却发生在 27 至 20 Ma 之间。子集样本的热模型结果表明,在最初的弥漫扩展变形之后,中新世中晚期(15-6 Ma)和上新世(<5 Ma)期间,分别在戈法省和Chew Bahir盆地内的一个狭窄地带发生了新的掘起。地壳冷却阶段与火山活动的区域趋势一致。例如,27 至 20 Ma 之间的初始冷却与大面积洪积玄武岩火山活动(45-28 Ma)的结束相吻合,这表明空间弥散的正断层可能是在大体积、大面积洪积玄武岩喷发后不久开始的。戈法省的马里-丹恰盆地和巴拉-凯拉盆地沿中新世和上新世的变形分别发生了变化,这可能表明在断裂晚期以及sMER和nKR之间持续的构造相互作用中出现了应变局部化。我们的研究结果支持大规模火山活动造成的地壳减弱是大范围伸展断裂的前兆这一观点,从而进一步揭示了东非大裂谷系统中岩浆辅助变形过程。
Magma-Assisted Continental Rifting: The Broadly Rifted Zone in SW Ethiopia, East Africa
The Gofa Province and Chew Bahir Basin in the Broadly Rifted Zone (BRZ) between the southern Main Ethiopian Rift (sMER) and the northern Kenya Rift (nKR) record early volcanism and associated faulting in East Africa; however, the spatiotemporal relationships between volcanism and faulting remain poorly constrained. We applied apatite (U-Th)/He (AHe) and zircon (U-Th)/He (ZHe) thermochronometry to Neoproterozoic basement rocks from exhumed footwall blocks of the extensional Gofa Province and Chew Bahir Basin, and analyzed our result in the context of well-dated regional volcanic units in the BRZ to unravel the interplay between tectonic exhumation, faulting and volcanism. Single-grain AHe ages ranging from 1.0 to 136.8 Ma were recorded in 32 samples, and single-grain ZHe ages from three samples range between 142.2 and 335.6 Ma. The youngest AHe ages were obtained from the Chew Bahir Basin and the narrow deformation zone in the Gofa Province. Our thermal modeling results reflect little or no significant regional crustal cooling prior to extensive volcanism, which started at about 45 Ma. Conversely, new and previously published thermal history models suggest that widespread crustal cooling related to regional extension occurred between ∼27 and 20 Ma. Thermal modeling results from subsets of samples indicate that following this initial diffuse extensional deformation, renewed exhumation occurred along a narrow zone within the Gofa Province and the Chew Bahir Basin during the middle to late Miocene (15-6 Ma) and Pliocene (<5 Ma), respectively. The crustal cooling phases follow a regional trend in volcanic episodes. For example, initial cooling between 27 and 20 Ma corresponds with the end of widespread flood-basalt volcanism (45–28 Ma), suggesting that spatially diffuse normal faulting may have initiated shortly after the emplacement of voluminous and areally extensive flood basalts. The Miocene and Pliocene shifts in deformation along the Mali-Dancha and Bala-Kela basins in the Gofa Province and the Chew Bahir Basin, respectively, may indicate strain localization during the late stage of rifting and ongoing tectonic interaction between the sMER and the nKR. Our results support the notion of crustal weakening by massive volcanism as a precursor to widespread extensional faulting, and thus offer further insights into magma-assisted deformation processes in the East African Rift System.
期刊介绍:
Tectonics (TECT) presents original scientific contributions that describe and explain the evolution, structure, and deformation of Earth¹s lithosphere. Contributions are welcome from any relevant area of research, including field, laboratory, petrological, geochemical, geochronological, geophysical, remote-sensing, and modeling studies. Multidisciplinary studies are particularly encouraged. Tectonics welcomes studies across the range of geologic time.