(alternatively Kikaiga-shima, Kikai Caldera Complex) is a massive, mostly submerged caldera up to in diameter in the Ōsumi Islands of Kagoshima Prefecture, Japan.
Geology
The Kikai Caldera is the southernmost caldera in the Kagoshima graben, a volcano-tectonic graben extending under the northeast East China Sea to the island of Kyushu in southern Japan.
The Kikai Caldera Complex has twin ovoid caldera by in diameter. The earliest definitive caldera formation has been dated back to at least 140,000 years ago, resulting from the eruption of Koabiyama pyroclastic flows.
Kikai-Koabiyama eruption
The Kikai-Koabiyama (K-Kob) pyroclastic flows are rhyolitic and are distributed across most of Takeshima and the plateau-like area on the northwest side of the caldera rim of Satsuma Iwo-Jima. They consist of numerous thin flow units and fill the basins in the basement, exhibiting significant variation in thickness. In Takeshima, the pyroclastic flows are thick, ranging from , whereas in Iwo Jima, they are relatively thin, measuring a few to .
Kikai-Tozurahara eruption
Kikai-Tozurahara (K-Tz) tephra is a widespread rhyolitic tephra layer of Late Pleistocene age, attributed to a large VEI-7 eruption from the Kikai caldera. This layer is confirmed to have a wide distribution, extending from south Kyushu to eastern Honshu and reaching the Pacific Ocean, and possibly including the Shandong Peninsula. The proximal equivalents of K-Tz are the Nagase pyroclastic flow and the Nishinoomote pyroclastic surges. The combined bulk volume of both distal and proximal deposits is estimated to exceed .
Kikai-Akahoya eruption
thumb|left|alt=Impact|Kikai-Kikai-Akahoya (K-Ah) [[tephra and pyroclastic flow impact from Kikai-Akahoya eruption]]
The caldera was the source of the Kikai-Akahoya eruption, one of the largest eruptions during the Holocene (10,000 years ago to present) that produced the Kikai-Akahoya (K-Ah) tephra. Between 7,200 and 7,300 years ago, pyroclastic flows producing Koya ignimbrite from that eruption reached the coast of southern Kyūshū up to away, and ash fell as far as Hokkaido. The eruption produced about DRE, most of it tephra. giving it a Volcanic Explosivity Index of 7,
The eruption had a major impact on the Jōmon culture in southern Kyūshū although the impact was not as great as some commentary had suggested with Nishinozono sub-type pottery tradition, that had started prior to the eruption, maintained in Kyūshū.
2024 studies
Japanese scientists conducted an extensive study of the volcanic activity of the Kikai underwater caldera. They had estimated the volumes of ejected volcanic material, which range from 332 to 457 cubic kilometers, and proved that it was the largest eruption in the last 11,700 years that occurred here 7,300 years ago. They were able to recreate the sequence of a large-scale volcanic event and identified three directions of flow of eruption products: in the atmosphere, along the seabed and along the water's edge.
Details of the marine expedition include conducting seismological studies and collecting sediment samples around the Kikai caldera. Scientists have confirmed that volcanic formations on the ocean floor and nearby islands have a common position. Analysis of the distribution of these deposits around the eruption site helps to understand how the pyroclastic flow and water interacted. The eruption occurred with a strong ejection of debris and ash, which corresponds to the usual phase of the Plinian type, during which there was a series of prolonged emissions under high pressure of fragmented lava and pumice in the form of a gas-ash mixture. It was a volumetric pyroclastic flow as a final stage, which partially spread along the seabed and released into the atmosphere in the form of an eruptive column (ash, fragments of pumice, small crystals and tephra). The tephra cloud covered an area of more than . The volume of ash material amounted to more than in terms of hard rock. The Plinian phase ended with the destruction of the eruptive column. A huge column of hot tephra fell a few hundred meters from the eruption's center, causing the formation of a pyroclastic flow.
Since the center of the volcano was under water, the Akahoya eruption had the character of a steam explosion (or a series of explosions) due to the instantaneous release of steam upon contact of hot magma with water. As a result, a double caldera was formed.
Scientists had conducted a detailed study of the spread of volcanic material over an area of about around the center of the eruption and mapped the thickness of the underwater pyroclastic sediment. In their opinion, 133 to of pumice and ash settled on the studied area.
After analyzing the textures and nature of the fragments of the underwater volcanic strata, the authors concluded that it was formed from a suspended stream, which can cover long distances even upslope, as it turned out. Having built a model of the Kikai-Akahoya eruption, researchers have found that in addition to the underwater pyroclastic flow and the powerful release of the tephra cloud into the atmosphere, there was also a third stream of thin volcanic material that spread along the surface of the water to the nearest islands.
Eruptive history since Kikai-Akahoya eruption
Kikai is still an active volcano. Io-dake (Mount Iō), Inamura-dake (south coast of Satsuma-Io-jima), Tokara-Iwo-Jima (north east coast of Satsuma-Io-jima), and Shōwa Iōjima (Shin-Io-jima) are post-caldera volcanoes within it.
- Old Iwo-dake stage (stage OIo-I-II)
- Phreatomagmatic eruptions and pumice fallout (stage OIo-I), followed by rhyolitic lava with continuous tephra, resulting in a volcanic edifice (stage OIo-II)
- 3250 BCE ± 75 years (uncalibrated) Old Iwo-dake
- OIo1a,b tephras