Low-frequency earthquakes beneath Tullu Moye volcano, Ethiopia, reveal fluid pulses from shallow magma chamber

Greenfield, Tim; Keir, Derek; Kendall, J.‐M.; Ayele, Atalay

doi:10.1016/j.epsl.2019.115782

Cited by 23 publications

(27 citation statements)

References 57 publications

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“…The temporal evolution, U ( t ) can be modeled by an exponential decay function,

U (t) = U_{\infty} (1 - e^{\frac{- t}{τ}})

, characterizing a hydraulic connection between two magma bodies (Lengliné et al., 2008; Rivalta, 2010) with an asymptotic displacement, U ∞ = 14 cm and characteristic time τ = 1.25 years (Figure 2e—pink solid line). These observations confirm the episodic behavior of this magmatic system and the exponential decay suggests a migration of fluids between two reservoirs, in agreement with seismic and MT studies (Greenfield et al., 2019a, 2019b; Samrock et al., 2018).…”

Section: Resultssupporting

confidence: 90%

“…The spatial extent of ground unrest correlates with the location of seismic swarms recorded during a campaign in 2016-2017 (Greenfield et al, 2019b). Although the majority of events are volcano-tectonic, two clusters located below Tullu Moje contained low-frequency waveforms that are likely to be triggered by pulses of hydrothermal fluids (H 2 O/CO 2 ) into a fractured region from a shallow magma body located 4-6.5 km below the surface (Greenfield et al, 2019a(Greenfield et al, , 2019b The Sentinel-1 survey detected a new pulse of ground deformation between the three volcanic centers-Tullu Moje, Bora, and Bericha-elongated in an NW-SE direction (Figure 2b). The deformation started in early 2016 at a rate of 5.8 ± 0.6 cm/yr (LOS descending), decreasing rapidly with time to an average rate of 1.9 ± 0.2 cm/ yr for the period 2017-2020 ( Figure 2e-red solid line).…”

Section: Tullu Moje (Mer)mentioning

confidence: 85%

“…The spatial extent of ground unrest correlates with the location of seismic swarms recorded during a campaign in 2016–2017 (Greenfield et al., 2019b). Although the majority of events are volcano‐tectonic, two clusters located below Tullu Moje contained low‐frequency waveforms that are likely to be triggered by pulses of hydrothermal fluids (H 2 O/CO 2 ) into a fractured region from a shallow magma body located 4–6.5 km below the surface (Greenfield et al., 2019a, 2019b).…”

Section: Resultsmentioning

confidence: 99%

See 2 more Smart Citations

Magmatic Processes in the East African Rift System: Insights From a 2015–2020 Sentinel‐1 InSAR Survey

Albino

Biggs

2021

Geochem Geophys Geosyst

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The East African Rift System (EARS) contains 78 volcanoes with records of Holocene activity (Global Volcanism Program, 2013) (Figure 1), but little is known about their past or present behavior. This lack of information makes it difficult to understand their eruptive cycles, their role in continental rifting or assess the threat they pose to the rapidly growing population. To fill this gap, it is necessary to collect information about past eruptions and to characterize present activity. On one hand, field studies can provide constraints on eruptive history, using tephrostratigraphy to estimate the age and magnitude of Quaternary eruptions (see Fontijn et al. (2018) for a review). On the other hand, geophysical ground-based observations help constrain the distribution of magmatic and/or hydrothermal fluids along the rift (

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“…The temporal evolution, U ( t ) can be modeled by an exponential decay function,

U (t) = U_{\infty} (1 - e^{\frac{- t}{τ}})

Section: Resultssupporting

confidence: 90%

Section: Tullu Moje (Mer)mentioning

confidence: 85%

Section: Resultsmentioning

confidence: 99%

See 1 more Smart Citation

Magmatic Processes in the East African Rift System: Insights From a 2015–2020 Sentinel‐1 InSAR Survey

Albino

Biggs

2021

Geochem Geophys Geosyst

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“…Instead, we propose that a weakening of the till resulting from the presence of fluid penetrating the till layer (Rathbun et al, 2008) or fluctuations in the hydraulic pressure caused by fluids (Röösli et al, 2016) may eventually result in a series of stick-slip events adjacent to regions of free water at the ice-bed interface. The role of fluids in promoting icequakes would also explain the temporal and spatial event clustering we observe (Fischer, Horálek, et al, 2014;Greenfield et al, 2019) and the large b-values (El-Isa & Eaton, 2014;Schlaphorst et al, 2017;Wilks et al, 2017). Large b-values are indicative for swarm-like earthquake behavior, which, in turn can be triggered from fluid induced pressure variations.…”

Section: Network Wide Icequake Distribution: Role Of Bed Topography mentioning

confidence: 74%

Not all Icequakes are Created Equal: Basal Icequakes Suggest Diverse Bed Deformation Mechanisms at Rutford Ice Stream, West Antarctica

et al. 2021

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Mass transfer from the ice sheet interior to the oceans is dominated by ice stream flow (Rignot et al., 2011), which, in turn, is governed by deformation within the ice, and friction and deformation at the bed, that is, the contact between ice and underlying sediments or bedrock. Furthermore, tidally induced modulations influence the flow dynamics of some ice streams, likely by introducing pressure modulation at the bed (Anandakrishnan et al., 2003; Gudmundsson, 2006). Poorly constrained processes and conditions at ice stream beds, therefore, contribute to the uncertainty in sea-level rise projections. Better understanding of the dynamic response of ice streams to a warming climate and oceans therefore requires improved models of these basal processes and the spatial variation in properties. Here, we focus on the understanding of basal sliding and deformation characteristics through the analysis of naturally occurring micro-earthquakes at the ice-bed interface. These events are used to examine the nature of basal slip, tidal influences, and spatial and temporal variations. The beds of ice streams consist of bedrock and sediment, often known as till. Till stiffness is variable and depends on the dynamic conditions and material properties. Ice flow at the bed is then facilitated by a combination of slip over a hard bed and by slip and deformation within a soft bed. Fluids further modulate basal ice stream flow. Where bedrock is exposed or subglacial till has relatively low permeability and is of Abstract Microseismicity, induced by the sliding of a glacier over its bed, can be used to characterize frictional properties of the ice-bed interface, which are a key parameter controlling ice stream flow. We use naturally occurring seismicity to monitor spatiotemporally varying bed properties at Rutford Ice Stream, West Antarctica. We locate 230,000 micro-earthquakes with local magnitudes from −2.0 to −0.3 using 90 days of recordings from a 35-station seismic network located ∼40 km upstream of the grounding line. Events exclusively occur near the ice-bed interface and indicate predominantly flow-parallel stick-slip. They mostly lie within a region of interpreted stiff till and along the likely stiffer part of mega-scale glacial lineations. Within these regions, micro-earthquakes occur in spatially (<100 m radius) and temporally (mostly 1-5 days activity) restricted event-clusters (up to 4,000 events), which exhibit an increase, followed by a decrease, in event magnitude with time. This may indicate event triggering once activity is initiated. Although ocean tides modulate the surface ice flow velocity, we observe little periodic variation in overall event frequency over time and conclude that water content, bed topography and stiffness are the major factors controlling microseismicity. Based on variable rupture mechanisms and spatiotemporal characteristics, we suggest the event-clusters relate to three end-member types of bed deformation: (1) continuous creation and seismogenic destruction of small-scale bed-roughness, (2...

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“…Over the past decade, a number of studies have sought to better understand the dynamics and eruptive histories of these volcanoes. Experiments have revealed a rich complexity of seismicity beneath Corbetti (Lloyd, et al, 2018a;Lavayssière et al, 2019), Bora-Tulu Moye (Greenfield et al, 2019a;Greenfield et al, 2019b) and Aluto (Wilks et al, 2017). Satellite imaging suggests frequently recurring and shallow magmatic activity (Biggs et al, 2011;Hutchison et al, 2016b;Lloyd et al, 2018a), and a role for pre-existing structures in the development of volcanism (Lloyd et al, 2018b).…”

Section: Introductionmentioning

confidence: 99%

The Coupled Magmatic and Hydrothermal Systems of the Restless Aluto Caldera, Ethiopia

et al. 2020

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Seismicity can be used to better understand interactions between magma bodies, hydrothermal systems and their host rocks-key factors influencing volcanic unrest. Here, we use earthquake data to image, for the first time, the seismic velocity structure beneath Aluto, a deforming volcano in the Main Ethiopian Rift. Traveltime tomography is used to jointly relocate seismicity and image 3D P-and S-wave velocity structures and the ratio between them (V P /V S). At depths of 4-9 km, the seismicity maps the top of a large low velocity zone with high V P /V S , which we interpret as a more ductile and melt-bearing region. A shallow (<3 km) hydrothermal system exhibits low seismic velocities and very low V P /V S (∼1.40), consistent with the presence of gases exsolved from a deeper melt-rich mush body. The Artu Jawe fault and fracture system provides the migration pathway that connects the deeper mush body with the shallow hydrothermal system. Together, these observations demonstrate that the interaction between magmatic and hydrothermal systems, driven by the exchange of fluids, is responsible for the restless behavior of Aluto.

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Low-frequency earthquakes beneath Tullu Moye volcano, Ethiopia, reveal fluid pulses from shallow magma chamber

Cited by 23 publications

References 57 publications

Magmatic Processes in the East African Rift System: Insights From a 2015–2020 Sentinel‐1 InSAR Survey

Magmatic Processes in the East African Rift System: Insights From a 2015–2020 Sentinel‐1 InSAR Survey

Not all Icequakes are Created Equal: Basal Icequakes Suggest Diverse Bed Deformation Mechanisms at Rutford Ice Stream, West Antarctica

The Coupled Magmatic and Hydrothermal Systems of the Restless Aluto Caldera, Ethiopia

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