A decade of volcanic construction and destruction at the summit of NW Rota‐1 seamount: 2004–2014

Schnur, S.; Chadwick, William W.; Embley, R. W.; Ferrini, V. L.; Ronde, C. E. J. de; Cashman, Katharine V.; Deardorff, N.; Merle, S. G.; Dziak, Robert P.; Haxel, J. H.; Matsumoto, Haru

doi:10.1002/2016jb013742

Cited by 28 publications

(29 citation statements)

References 54 publications

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“…At Monowai, which has a similar summit depth as Ahyi (<150 m), intermittent eruptive activity over many years has been interspersed with multiple landslides on different sectors of the volcano (Chadwick, Wright, et al, ; Watts et al, ; Wright et al, ). Similarly at NW Rota‐1, low‐level strombolian eruptive activity between 2003 and 2009 deposited volcaniclastic deposits on the upper southern slope of the volcano, which were then moved downslope in a major landslide in 2009 (Chadwick et al, ; Chadwick et al, ; Embley et al, ; Schnur et al, ). West Mata volcano was observed to be erupting continuously between 2008 and 2011 by direct ROV observations and remote hydrophone recordings (Dziak et al, ; Resing et al, ).…”

Section: Interpretation and Discussionmentioning

confidence: 99%

Hydroacoustic, Seismic, and Bathymetric Observations of the 2014 Submarine Eruption at Ahyi Seamount, Mariana Arc

Tepp

Chadwick

Haney

et al. 2019

Geochem Geophys Geosyst

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Ahyi seamount, a shallow submarine volcano in the Northern Mariana Islands, began erupting on 23 April 2014. Hydroacoustic eruption signals were observed on the regional Mariana seismic network and on distant hydrophones, and National Oceanic and Atmospheric Administration (NOAA) scuba divers working in the area soon after the eruption began heard and felt underwater explosion sounds. The NOAA crew observed yellow‐orange bubble mats along the shore of neighboring Farallon de Pájaros Island, but no other surface manifestations of the eruption were reported by the crew or observed in satellite data. Here, we detail the eruption chronology and its morphologic impacts through analysis of seismic and hydroacoustic recordings and repeat bathymetric mapping. Throughout the 2‐week‐long eruption, Ahyi produced several thousand short, impulsive hydroacoustic signals that we interpret as underwater explosions as well as tremor near the beginning and end of the sequence. The initial tremor, which occurred for 2 hr, is interpreted as small phreatomagmatic explosions. This tremor was followed by a 90‐min pause before the characteristic impulsive signals began. Occasional tremor (lasting up to a few minutes) during the last 1.5 days of the eruption is interpreted as more sustained eruptive activity. Bathymetric changes show that a new crater, about 150 m deep, formed near the former summit and a large landslide chute formed on the southeastern flank. Comparing to other geophysically detected submarine eruptions, we find that the signals from the 2014 Ahyi eruption were more similar to those from other shallow or at‐surface submarine eruptions than those at deep (>500 m) eruptions.

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Section: Interpretation and Discussionmentioning

confidence: 99%

Hydroacoustic, Seismic, and Bathymetric Observations of the 2014 Submarine Eruption at Ahyi Seamount, Mariana Arc

Tepp

Chadwick

Haney

et al. 2019

Geochem Geophys Geosyst

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“…The 2014 expedition was more limited in scope but included revisiting sites along the arc that had not been sampled since 2006, sampling one additional site on the back-arc (Urashima), and returning to NW Rota-1 (Supporting Information Fig. S2) to find greatly decreased volcanic activity relative to all prior visits in the previous decade (Schnur et al, 2017).…”

Section: Site Descriptions and Sample Collectionmentioning

confidence: 99%

Hydrothermal vent protistan distribution along the Mariana arc suggests vent endemics may be rare and novel

Murdock

Juniper

2019

Environmental Microbiology

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Summary Elucidation of the potential roles of single‐celled eukaryotes (protists) in ecosystem function and trophodynamics in hydrothermal vent ecosystems is reliant on information regarding their abundance, distribution and preference for vent habitats. Using high‐throughput 18S rRNA gene sequencing on a diverse suite of hydrothermally influenced and background water samples, we assess the diversity and distribution of protists and identify potential vent endemics. We found that 95% of the recovered sequences belong to operational taxonomic units (OTUs) with a cosmopolitan distribution across vent and non‐vent habitats. Analysis of ‘vent only’ OTUs found in more than one vent sample and co‐occurrence network analysis comparing protist groups to extremophilic reference organisms suggest that the most likely vent endemics are infrequently encountered, potentially in low abundance, and belong to novel lineages, both at the phylum level and within defined clades of Rhizaria and Stramenopila. Potential endemism is inferred for relatives of known apusomonads, excavates and some clades of Syndiniales. Similarity in community composition among samples was low, indicating a strong stochastic component to protist community assembly and suggesting that rare endemics may serve as a reservoir poised to respond to changing environmental conditions in these dynamic systems.

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“…For example, at the fast-spreading EPR, vent communities have been observed to be eradicated by seafloor eruptions on decadal time scales (Rubin et al, 2012), but at the slow-spreading MAR an eruption might not occur for 10,000 years (Perfit and Chadwick, 1998). Some arc volcanoes "grow and collapse on human timescales" due to frequent eruptions as well as landslides (Schnur et al, 2017). Other non-volcanic natural disturbances, such as earthquake activity or cessation of a vent within the patch, may lead to minor to moderate disturbances that affect patch size or quality.…”

Section: Global Patterns Of Vent Distributions Disturbance Frequencymentioning

confidence: 99%

“…Disturbance may also create new habitat. The frequency of disturbance may range from almost continuous at vents on submarine arc volcanoes with multiyear eruptions (e.g., NW Rota-1; Rubin et al, 2012;Schnur et al, 2017) to very infrequent at vents hosted in ultraslow spreading settings. At spreading ridges, the frequency of volcanic eruptions is related to timeaveraged magma supply and spreading rate (Perfit and Chadwick, 1998).…”

Section: Global Patterns Of Vent Distributions Disturbance Frequencymentioning

confidence: 99%

Exploring the Ecology of Deep-Sea Hydrothermal Vents in a Metacommunity Framework

et al. 2018

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Species inhabiting deep-sea hydrothermal vents are strongly influenced by the geological setting, as it provides the chemical-rich fluids supporting the food web, creates the patchwork of seafloor habitat, and generates catastrophic disturbances that can eradicate entire communities. The patches of vent habitat host a network of communities (a metacommunity) connected by dispersal of planktonic larvae. The dynamics of the metacommunity are influenced not only by birth rates, death rates and interactions of populations at the local site, but also by regional influences on dispersal from different sites. The connections to other communities provide a mechanism for dynamics at a local site to affect features of the regional biota. In this paper, we explore the challenges and potential benefits of applying metacommunity theory to vent communities, with a particular focus on effects of disturbance. We synthesize field observations to inform models and identify data gaps that need to be addressed to answer key questions including: (1) what is the influence of the magnitude and rate of disturbance on ecological attributes, such as time to extinction or resilience in a metacommunity; (2) what interactions between local and regional processes control species diversity, and (3) which communities are "hot spots" of key ecological significance. We conclude by assessing our ability to evaluate resilience of vent metacommunities to human disturbance (e.g., deep-sea mining). Although the resilience of a few highly disturbed vent systems in the eastern Pacific has been quantified, these values cannot be generalized to remote locales in the western Pacific or mid Atlantic where disturbance rates are different and information on local controls is missing.

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A decade of volcanic construction and destruction at the summit of NW Rota‐1 seamount: 2004–2014

Cited by 28 publications

References 54 publications

Hydroacoustic, Seismic, and Bathymetric Observations of the 2014 Submarine Eruption at Ahyi Seamount, Mariana Arc

Hydroacoustic, Seismic, and Bathymetric Observations of the 2014 Submarine Eruption at Ahyi Seamount, Mariana Arc

Hydrothermal vent protistan distribution along the Mariana arc suggests vent endemics may be rare and novel

Exploring the Ecology of Deep-Sea Hydrothermal Vents in a Metacommunity Framework

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