UNIT 1 IMAGE GALLERY
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Spider Crab on New Flow
A spider crab and 1500 m water depth walks across a glassy, jumbled sheet flow in the International District vent field. Credit: UW/NSF-OOI/WHOI; V19.
Deep-sea octopus dining on Escargot
The large pink octopus (likely Muusoctopus sp.) sits on a ledge at Escargot hydrothermal vent in the International District Hydrothermal Field. Credit: UW/NSF-OOI/CSSF; ROPOS Dive R1719; V14.
Fried Egg Jelly on the seafloor
This large jelly is called a Fried Egg Jelly (Phacellophora cantschatica). It normally is a pelagic organism, however this one is on the seafloor, making it vulnerable to spider crab feasting. Photo credit: NSF-OOI/UW/CSSF; Dive R1619; V13
Lava Whirl At Axial
A fossilized lava pond reflects past circulation of melt on the seafloor in a small lava lake. The surface is glass, and fine sediments highight the whirl. VISIONS '13, Leg 4
Photo credit: NSF-OOI/UW/CSSF
Bathrub Rings Collapsed Lava Lake
"Bathtub" rings mark the egress of lava in collapsed lava lake from the 2011 eruption in Axial Caldera. Credit: UW/NSF-OOI/WHOI; V17.
Pillar Stands in a Collapsed Lava Lake
A basaltic pillar stands in a collapsed lava lake from the 2011 eruption in Axial Caldera. "Bathtub rings mark the egress of lava. Credit: UW/NSF-OOI/WHOI; V17.
Basaltic Arches in a Lava Lake
Arches capped by glassy basalts remain in a collapsed lava lake at the summit of Axial seamount. Credit: UW/NSF-OOI/WHOI; V17.
Odd Basalt Formation and Tubeworms
An odd basalt formation at the edge of a small, collapsed and frozen lava lake is colonized by tubeworms. Credit: UW/NSF-OOI/WHOI; V17.
An Underwater Lava Cave
An underwater cave filled with rubble from a collapsed lava lake is capped by glassy flows. Credit: UW/NSF-OOI/WHOI; V17.
Sheet Flows and Lobate Follows Axial Wall
Cross sectional view of lobate flows and sheet flows on the western wall of Axial Seamouint hosting sea anemones and starfish. Credit: UW/NSF-OOI/ROPOS; V22.
Beautiful Pillow Basalts
Beautiful pillow basalts with classic bread crust outer surfaces on Axial Seamount. Credit: UW/NSF-OOI/CSSF; V14.
Lobate and Jumbled Flows
Rat tail fish explore lobate and jumbled lava flows atop Axial Seamount. Credit: UW/NSF-OOI/CSSF; V14.
Pillow Basalts at the Summit of Axial Seamount
Pillow basalts and sedimented lobate flows at the summit of Axial Seamount. Credit: UW/NSF-OOI/CSSF; V14.
Breached Pillow Basalt 2015 Eruption
Frozen fluid lava exits the toe of a pillow basalt on the north face of the >400 ft thick lava flow formed during the 2015 eruption of Axial Seamount. Credit: UW/NSF-OOI/CSSF; V15.
Old Pillow Flows
Lightly sedimented pillow flows hosting brittle stars and a coral on Axial Seamount. Credit: UW/NSF-OOI/CSSF; ROPOS Dive R1473; V11.
Life Thrives at Inferno
Beautiful red plumes top the ends of tube worms that are associated with scale worms, limpets and sulfide worms on the Inferno chimney in the ASHES Hydrothermal Field. Credit: D. Kelley, University of Washington, Bureau of Ocean Energy Management, WHOI; V21.
Tubeworms
Tube worms thrive on the side of the active >270°C vent called Inferno in the ASHES vent field. Credit: UW/OOI-NSF/WHOI; V19.
The multi-spire top of Inferno
The top of Inferno hosts numerous actively venting spires that change yearly. Credit: UW/NSF-OOI/WHOI: V20
Limpets and Scale Worms
Organisms colonize the outer walls of the 16 m-tall hydrothermal edifice called El Guapo. The community structure changes with height above seafloor. Here, limpets, red scale worms and blue protists (ciliates) colonize the outer sulfide walls of the structure. Credit: UW/NSF-OOI/WHOI, V18.
Mid-Ocean Ridge Spreading Centers
A map of seafloor magnetics highlights the mid-ocean ridge spreading center network that forms the longest mountain chain on Earth. Credit: Center for Environmental Visualization, UW.
Seafloor Spreadig and Subduction
Convection cells beneath mid-ocean ridges (divergent plate boundaries) are sites where melt rises up from the mantle. At convergent plate boundaries the oceanic crust and sediments are subducted beneath the bounding plate. Credit: Center for Environmental Visualization, UW.
Cascade Volcanoes
During subduction of the Juan de Fuca (JdF) Plate beneath the North American Plate, ocean crust and overlying sediments being carried downward heat up, releasing water and other gases into the overlying plate, causing melts to form ~ 50 miles beneath the volcano. Images of the volcanoes are in the USGS public domain. In conrast, Axial Seamount is formed by melts rising from beneath the JdF spreading center that forms the plate boundary between the Pacific Plate and the JdF Plate. Credit. D. Kelley, University of Washington.
Bathymetric Map of the Juan de Fuca Plate
A basic bathymetric map centered on the Juan de Fuca Plate. Credit: Credit: Center for Environmental Visualization, UW.
Tectonic Plates off North America
Bathymetric map showing the tectonic plates from California north to Vancover Island.
Credit: Center for Environmental Visualization and D. Kelley, University of Washington.
Tectonic Plates Vancouver Island to California
Tectonic plates off Vancouver Island south to California. Credit: Center for Environmental Visualization and D. Kelley, University of Washington.
Transform Faults
Transform faults and fracture zones bounding tectonic plates off Vancouver Island south to California. Credit: Center for Environmental Visualization and D. Kelley, University of Washington.
Spreadin Centers off North Ameria and Canada
The intermediate spreading Juan de Fuca Ridge hosts multiple segments. A hot spot underlies the ridge beneath Axial Seamount. The Cobb-Eickeberg Seamount chain marks the migration of the Pacific Plate over time. Transform faults and fracture zones bounding tectonic plates off Vancouver Island south to California. Credit: Center for Environmental Visualization and D. Kelley, University of Washington.
Axial Seamount
Axial Seamount rises to a depth of ~ 1500 m beneath the oceans surface and is cut by the Juan de Fuca Ridge. Transform faults and fracture zones bounding tectonic plates off Vancouver Island south to California. Credit: Center for Environmental Visualization and D. Kelley, University of Washington.
Cobb Seamount
Cobb Seamount is ~ 100 km west of the Cobb hot spot, currently feeding Axial Seamount on the Juan de Fuca Ridge. It is ~ 3.3 Ma in age. The flat-topped summit is at a depth of 200-300 m. It was formed when the summit was above sea level. The inset of Cobb is after Chaytor et al., Seamount morphology in the Bowie and Cobb hot spot trails, Gulf of Alaska. Geochem. Geophys. Geosyst., doi:10.1029/2007GC001712. Credit. D.S. Kelley, University of Washington.
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Graphing the Ocean Floor.001
Bathymetric Map of Axial Caldera
This bathymetric map shows the location of the 2011 and 2015 lava flows in the caldera of Axial Seamount and along the northern rift and the hydrothermal fields (e.g. International District) and diffuse flow sites and other vents. Credit: M. Elend, University of Washington. The bathymetry is courtesy of D. Caress, Monterey Bay Aquarium Research Institute.
Axial Gallery
Environments at Axial Seamount
RCA Instruments
Axial Seismometers
RCA Seismometers
The RCA hosts an array of seismometers associated with Axial Seamount and the Cascadia Margin. Credit: University of Washington.
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Axial Seamount Earthquakes
Axial Seamount 2015 127 m thick Eruption
The 2015 eruption of Axial Seamount along the northern rift culminated in a 127 m thick lava flow. Three months after the eruption, during the Regional Cabled Array VISIONS'15 cruise, the remotely operated vehicle ROPOS captured the first images of the flow, landing 10 m away from its base. The summit was covered in acres of microbial mats. Credit. D. Kelley, University of Washington, UW/NSF-OOI/CSSF
Why study Volcanoes
Where volcanoes form.001
The Ring of Fire and Volcanoes
This animation shows the relationship between earthquakes and the location of volcanoes around the "ring of fire". Credit: UW Center for Environmental Visualization.
Plate Tectonics and the Ocean Floor
Topographic map of Earth, modified from NOAA (Amante et al., 2009) showing features of the seafloor. Credit: D. Kelley, University of Washington.
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Broadband Seismometer Connection Central Caldera
The broadband seismometer (left) and low frequency hydrophone (right) are installed on the floor of Axial Seamount at the Central Caldera Site. The 7-function manipulator of ROPOS is connecting the extension cable to the medium powered junction box. The white bags inssulate the broadband from acoustic "noise" associated with curents flowing over the instrument.
Broadband Seismometer and Hydrophone
The broadband seismometer and hydrophone being installed at the Central Caldera site on Axial Seamount. Credit: UW/NSF-OOI/CSSF; V14
Short Period Seismometer Deployed
This short-period seismometer was deployed on a flat sheet flow ~ 1.3 km east of the ASHES hydrothermal field in 2013. The black ball in the yellow circle shows that it is perfectly level, helping to insure that the highest quality data comes off of this network. Axial Volcano is likely to be quite seismically active and we are anxious to get the real-time data on shore next year. This will help us understand magma and fluid migration in the subsurface of the volcano...and eventually these data may help us predict an eruption. Several earthquakes were detected in real-time during testing of these seismometers in 2013. Credit: UW/NSF-OOI/CSSF, ROPOS Dive R1635; V13.
Ash from the 2015 Axial Eruption
Ash (glass shards) rest atop a leveling component on the bottom pressure tilt instrument at the Central Caldera site. Credit: UW/NSF-OOI/CSSF. V15
Reminiscent of Monet
Beautiful blue ciliates, and white and yellow bacterial mats in the Tiny Towers vent site are imaged live by the ROV Jason. Credit: D. Kelley, University of Washington; V19.