Development of the Nyika Plateau, Malawi: A Long Lived Paleo‐Surface or a Contemporary Feature of the East African Rift?

McMillan, M. F.; Boone, Samuel C.; Kohn, Barry P.; Gleadow, A. J. W.; Chindandali, P. R. N.

doi:10.1029/2022gc010390

Cited by 9 publications

(4 citation statements)

References 131 publications

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“…Accardo et al (2018) observe an extensive deep zone of material with P-wave velocities intermediate between sediment and crust (3.75-4.5 km/s) that crosscuts the rift at this accommodation zone between the North and Central Basins and extends into the center of the Central Basin; these observations provide the first direct evidence that an earlier rift package may underlie the present phase of EARS-related deformation. This observation is supported by similar trends in low-temperature thermochronology data from either side of the lake (McMillan et al, 2022). It is not clear if these ancient structures provide a mechanistic control on strain partitioning between border and intrarift faults within the Lake Malawi Rift.…”

Section: The Malawi Riftmentioning

confidence: 75%

Heterogeneous Strain Distribution in the Malawi (Nyasa) Rift, East Africa: Implications for Rifting in Magma‐Poor, Multi‐Segment Rift Systems

Wright,

Scholz,

Muirhead

et al. 2023

Tectonics

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Half‐graben basins bounded by border faults typify early‐stage continental rifts. Deciphering the role that intra‐rift faults play in rift basin development is challenging as patterns of early‐stage faulting are commonly overprinted by subsequent deformation; yet the characterization of these faults is crucial to understand the fundamental controls on their evolution, their contribution to rift opening, and to assess their seismic hazard. By integrating multiple offshore seismic reflection data sets with age‐dated drill core, late‐Quaternary and cumulative faulting patterns are characterized in the Central and South Basins of the Malawi (Nyasa) Rift, an active, early‐stage rift system. Almost all intra‐rift faults offset a late‐Quaternary lake lowstand surface, suggesting they are active and should be considered in hazard assessments. Fault throw profiles reveal sawtooth patterns indicating segmented slip histories. Observed extension on intra‐rift faults is approximately twice that predicted from hanging wall flexure of the border fault, suggesting that intra‐rift faults accommodate a proportion of the regional extension. Cumulative and late‐Quaternary throws on intra‐rift faults are correlated with throw measured on the border fault in the Central Basin, whereas an anticorrelation is observed in the South Basin. Viewed in a regional context, these differences do not relate solely to the proposed southward younging of the rift. Instead, it is inferred that the distribution of extension is also influenced by variations in lithospheric structure and crustal heterogeneities that are documented along the rift axis.This article is protected by copyright. All rights reserved.

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Section: The Malawi Riftmentioning

confidence: 75%

Heterogeneous Strain Distribution in the Malawi (Nyasa) Rift, East Africa: Implications for Rifting in Magma‐Poor, Multi‐Segment Rift Systems

Wright,

Scholz,

Muirhead

et al. 2023

Tectonics

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“…However, precipitation is not the only driver of the elevated erosion rates, as the greatest precipitation rates occur farther north across the Songwe catchment, which has lower average erosion rates than the N. Rumphi and N. Rukuru. Both these catchments instead drain the Nyika plateau, a 3,700 km 2 highly elevated (∼2,500 m) region which formed as a response to Karoo rifting during the Late‐Paleozoic (Dixey, 1937a, 1937c; McMillan et al., 2022). This elevated region of topography (Figures 1 and 6) results in greater relief, higher average slopes and smaller catchment area (∼800–2,000 km 2 ) compared to the other catchments across the rift.…”

Section: Discussionmentioning

confidence: 99%

Spatio‐Temporal Variations in Sediment Delivery as a Response to Rapid Quaternary Climate Change in the Lake Malawi Rift, East Africa

Wright,

Scholz

2023

JGR Earth Surface

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The interplay of rapid climate change and tectonics drives landscape development, sediment routing, and deposition in early‐stage continental rift systems. The Lake Malawi Rift, in the Western Branch of the East African Rift, is an archetype of a juvenile rift and an ideal natural laboratory for evaluating lacustrine source‐to‐sink systems on orbital or shorter timescales. We examine the interplay of these processes over the past 140 kyr using observations from nested seismic reflection data sets tied to scientific drill cores, which calibrate numerical forward models of this closed sedimentary system. Fault slip rates measured from seismic data drive tectonic displacements in the model. Satellite‐derived precipitation maps constrain modern precipitation and are scaled to previous hydrologic balance studies to reconstruct past climates. Our model reproduces known sediment thicknesses across the rift and accounts for 96% of the estimated siliciclastic sediment deposited over the past 140 kyr. The results demonstrate that the onset of arid climate conditions (140–95 kyr BP) causes extreme drainage adjustments downstream and the formation of mega‐catchments that flow axially into a shallow restricted paleo‐lake. Sedimentation rates during this time are twice the present values due to increased sediment focusing via these axial systems into a much smaller, hydrologically closed lake. As the climate became wetter (95–50 kyr BP), the lake rapidly expanded, decreasing both erosion and sedimentation rates across the rift. This closed‐loop approach allows us to evaluate the role of high‐frequency climate change in modulating basin physiography as well as sediment fluxes in juvenile rift systems.

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“…Subsequent to the Pan‐African transpression, continental‐scale Karoo rifting that occurred primarily in the Permian‐Triassic and culminated with the Jurassic Gondwana break‐up led to the formation of several NE‐SW trending sedimentary basins in Malawi (Figure 1; Castaing, 1991; Catuneanu et al., 2005). These sedimentary basins are confined to upper‐crustal depths with Karoo sediments in Malawi reaching thicknesses of up to 3 km (Castaing, 1991; Geological Survey of Malawi, 1966), although this may be an under‐estimate as significant thicknesses of Karoo sediments may have been eroded (McMillan et al., 2022). Although preserved in the topography and sedimentary record, faults defining the main NE‐SW trending Karoo basins of Malawi show little sign of current tectonic reactivation (Figure 1a; Castaing, 1991).…”

Section: Regional Geology Tectonics and Thermal Structurementioning

confidence: 99%

Metamorphic Inheritance, Lower‐Crustal Earthquakes, and Continental Rifting

Fagereng,

Diener,

Tulley

et al. 2024

Geochem Geophys Geosyst

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The Malawi Rift is localized within Precambrian amphibolite‐granulite facies metamorphic belts, bounded by up to 150 km long border faults, and generates earthquakes throughout ∼40 km thick crust. Rift‐related faults are inferred to exploit pre‐existing weaknesses that allow rifting of otherwise dry and strong crust. It is unclear what these weaknesses are, and how localization into weak zones can be reconciled with strength required for lower crustal seismicity. We present results of mineral equilibria modeling, which indicate that Proterozoic metamorphism generated dry crust dominated by a quartz‐feldspar assemblage that is metastable at current conditions. For rift propagation to be possible at current cool thermal gradients and in mechanically strong, dry quartzofeldspathic rocks, mid‐ to lower‐crustal strain must be localized into relatively weak, inherited shear zones that deform primarily by aseismic, viscous creep. These shear zones are embedded within high‐strength crust, and interaction between creeping shear zones and enveloped or surrounding rocks may locally increase stress and trigger frictional, seismic slip at mid‐ to lower‐crustal depths. Over time, this interaction may produce a fracture network that allows infiltration of fluids. We therefore suggest that during rifting of previously deformed and metamorphosed crust, major faults are most likely to grow from below, with their location and orientation prescribed by underlying inherited viscous shear zones. In this case, fluids may infiltrate and locally weaken metastable lower crust, including allowing time‐dependent fluid‐driven seismicity and local partial melting, but length‐scales of this weakening is limited by the scale of the permeability network.

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Development of the Nyika Plateau, Malawi: A Long Lived Paleo‐Surface or a Contemporary Feature of the East African Rift?

Cited by 9 publications

References 131 publications

Heterogeneous Strain Distribution in the Malawi (Nyasa) Rift, East Africa: Implications for Rifting in Magma‐Poor, Multi‐Segment Rift Systems

Heterogeneous Strain Distribution in the Malawi (Nyasa) Rift, East Africa: Implications for Rifting in Magma‐Poor, Multi‐Segment Rift Systems

Spatio‐Temporal Variations in Sediment Delivery as a Response to Rapid Quaternary Climate Change in the Lake Malawi Rift, East Africa

Metamorphic Inheritance, Lower‐Crustal Earthquakes, and Continental Rifting

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