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Subaqueous volcano

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White Horse Bluff

A subaqueous volcano is a volcano formed from the eruption or flow of magma that occurs underwater (as opposed to a subaerial volcanic eruptions).[1] Subaqueous volcanic eruptions are significantly more abundant than subaerial eruptions and are estimated be responsible for 85% of global volcanism by volume.[2]

They are commonly in the form of gently sloping tuff cones, although they can have more vertical appearance similar to that of a mountain, such as White Horse Bluff in the Wells Gray-Clearwater volcanic field of east-central British Columbia, Canada.[3]

Comparison to subaerial volcanoes

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Subaqueous volcanoes can be compared to subaerial volcanoes which are formed and erupt on land. The major differences of volcanic eruptions are due to the effects of pressure, heat capacity or thermal conductivity of water, the presence of steam and water rheology. The thermal conductivity of water is about 20 times that of air and steam has a thermal conductivity nearly 50 times that of water.[4] The study of subaqueous volcanoes has changed substantially. Modern studies offer fresh and unaltered observances can see and map surface features and the water depth is known in areas that allow observation. Ancient studies have had stratigraphic exposure to sections, are easier to work on, have more and better exposures and have an existing relationship to resources.[5]

Subaqueous pyroclastic flows

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Some geologists restrict the term "subaqueous pyroclastic flow deposits" to volcaniclastic units that show characteristics of emplacement in a hot state deposited underwater. However, this cannot always be done because of the subsequent process of alteration or diagenesis such as can be found in active hot springs and the associated hydrothermal alteration. Deposits from pyroclastic flows that interact with water then transform into water-supported mass flows are called "subaqueous pyroclastic debris flow deposits" by some geologists.[6][7]

On the other hand, processes that are associated with eruption, transportation and deposition are notably different because of the presence of water, including the ability to vaporize when in contact with water, a high density and resulting confining pressure, high viscosity relative to air and differences in the thermal conductivity/specific heat capacity of air relative to water.[4]

Deposits in Honshu

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Some understanding of subaqueous volcanoes can be inferred from knowledge of volcanic processes based on ancient successions. Subaqueous volcano deposits have been occurring in the south of Honshu, the largest island among Japan's four principal islands. The four subaqueous volcanic deposits that have been documented offer significant evidence to study.

Features

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Subaqueous sedimentary deposits

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Subaqueous volcanic deposits are associated with subaqueous sedimentary deposits and these deposits range from near shore, off-shore and abyssal mudstone deposits. Unfortunately, paleo-depth constraints for sedimentary strata are poor and subject to contradicting interpretations. However, the depth of emplacement can be conjectured with minor control of water depth. In determining the characteristics of pyroclastic flows in subaerial versus subaqueous deposits, it is commonly believed that water fluidized volcaniclastic flows become normally graded in terms of all components except for large, buoyant pumice blocks which settle to form large pumice layers. However, this phenomenon is usually seen as subaerial ignimbrite (pumice rich pyroclastic flows) deposits. Because of this, the characteristic is not considered clear evidence for the interpretation of the fluidizing agent (hot gas or water) and can therefore only be used in conjunction with other criteria.

Characteristics

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Characteristics can be sorted to infer subaqueous eruption or emplacement of silicic pyroclastic deposits. Larger pumice blocks rise for a more extended period of time (minutes to hours) in comparison to smaller pumice fragments because of gases trapped within vesicles and the very fine ash fragments may become entrained into the rising plume of gas and heated water because of the low density and weight. Therefore, subaqueous silicic pyroclastic eruptions may be diminished in the course size fraction as well as the very fine ash size fraction based on the buoyancy of the material in the water medium. These characteristics may be important in determining the style of subaqueous eruption and emplacement mechanism. The characteristics of texture, such as grain morphology and grain size abundances can also provide knowledge on the process of controlling the eruption style or transport/flow properties, whether turbulent or laminar.

Seafloor exploration

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Seafloor exploration has discovered that more volcanic eruptions occur at the bottom of the sea than on land. However, the effects of ambient water and hydrostatic pressure on silicic volcanic eruptions in subaqueous settings are not entirely understood because deep marine eruptions are not directly observed and studied. Because of this, information of recent deep-water volcanic eruptions are still incomplete and limited.

Conclusions

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The conclusions of the studies of subaqueous volcanoes in Japan determine that clear evidence for eruption and/or emplacement of pyroclastic flows continue to be determined from the examination of these deposits although inferential evidence such as grain morphology, sorting and grading can be used to identify and document ancient subaqueous volcanic deposits. The University of California, Santa Barbara will continue to conduct further research which may be able to provide further information on styles of subaqueous volcanic eruptions and/or flow characteristics of volcanic deposits.[8]

References

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  1. ^ Earle, Steven (September 23, 2019). "Chapter 4 Volcanism". Physical Geology (2nd ed.). BCcampus. ISBN 978-1-77420-028-5.{{cite book}}: CS1 maint: date and year (link)
  2. ^ White, James D.L.; Smellie, John L.; Clague, David A. (2003), White, James D. L.; Smellie, John L.; Clague, David A. (eds.), "Introduction: A deductive outline and topical overview of subaqueous explosive volcanism", Geophysical Monograph Series, 140, Washington, D. C.: American Geophysical Union: 1–23, Bibcode:2003GMS...140....1W, doi:10.1029/140gm01, ISBN 978-0-87590-999-8, retrieved July 5, 2024
  3. ^ "Catalogue of Canadian volcanoes - Wells Gray - Clearwater volcano field". Archived from the original on October 8, 2006.
  4. ^ a b "Subaqueous Pyroclastic Flows" (PDF). University of Minnesota. November 16, 2010. Archived from the original (PDF) on November 29, 2014. Retrieved July 22, 2023.
  5. ^ Morton, Ron (August 19, 2008). "Subaqueous Volcanism" (PDF). University of Minnesota. Archived from the original (PDF) on October 20, 2014. Retrieved July 23, 2023.
  6. ^ Carey, Steven N.; Sigurdsson, Haraldur (February 1980). "The roseau ash: Deep-sea tephra deposits from a major eruption on Dominica, lesser antilles arc". Journal of Volcanology and Geothermal Research. 7 (1–2): 67–86. Bibcode:1980JVGR....7...67C. doi:10.1016/0377-0273(80)90020-7.
  7. ^ de Haas, Tjalling; Santa, Nikoleta; de Lange, Sjoukje I.; Pudasaini, Shiva P. (September 2020). "Similarities and contrasts between the subaerial and subaqueous deposits of subaerially triggered debris flows: An analogue experimental study". Journal of Sedimentary Research. 90 (9): 1128–1138. Bibcode:2020JSedR..90.1128D. doi:10.2110/jsr.2020.020.
  8. ^ "ssr#00-04". www.nsf.gov. March 5, 2024.