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Raikoke (Russian: Райкоке, Japanese: 雷公計島, romanizedRaikoke-tō), also spelled Raykoke, is, as of 2019, a Russian uninhabited volcanic island near the centre of the Kuril Islands chain in the Sea of Okhotsk in the northwest Pacific Ocean, 16 kilometres (9.9 mi) distant from the island of Matua. Its name is derived from the Ainu language, from the Hokkaido Ainu word "hellmouth".[citation needed]

Key Information

Geology

[edit]

Raikoke is roughly circular, with a length of 2.5 km (1.6 mi) with a width of 2.0 kilometres (1.2 mi), and an area of 4.6 km2 (1.8 sq mi).[1] The island is a stratovolcano, its lava composed primarily of basalt.[2] The cone rises above a submarine terrace with a depth of 130 m (430 ft) to a maximum height of 551 m (1,808 ft) above sea level. The steep-walled crater is 700 m (2,300 ft) wide and 200 m (660 ft) deep with lava flows extending along the eastern half of the island. The volcano has most recently erupted in 1765, 1778, 1924 and 2019.[3] The 1778 and 1924 Raikoke eruptions were classified on the Volcanic Explosivity Index scale (that ranges from zero to eight) as VEI-4 or greater. For comparison the volcano Anak Krakatoa eruption in 2018 was also rated as a VEI-4 event.[4][5][3] The 1778 eruption of Raikoke was the largest of the recent volcanic events destroying the upper third of the island.[6] The only known fatalities from the eruptions was during the 1778 eruption when fifteen were killed from falling lava bombs.[3]

2019 eruption

[edit]
Raikoke emits a plume of ash and volcanic gases in the 2019 eruption.

At approximately 4:03 am, 22 June 2019 it erupted, with a plume of ash and gas reaching between 13,000 m (43,000 ft) and 17,000 m (56,000 ft), passing the tropopause and allowing stratospheric injection of ash and sulfur dioxide.[7]

A study with the ESA satellite Sentinel-5P revealed volcano's sulphur dioxide plume had clustered into distinct structures in the 72 hours following the eruption. One of these plumes was a swirling stratospheric mass of sulphur dioxide that circled the globe three times and ascended to an altitude of some 27 km (17 mi) through the radiative heating of ash. Sentinel-5P and NASA's CALIPSO mission showed signs of anticyclonic motion for this plume. The ESA satellite Aeolus confirmed that the structure was anticyclonic. Such self-containing and long-lived anticyclonic structures have long been associated with large wildfires, but stable volcanic plumes are seldom reported and only form in certain conditions.[8]

Fauna

[edit]

Raikoke is one of five major Steller sea lion rookeries on the Kuril Islands and in the spring and summer it is home to one of the largest northern fulmar aggregations on the Kurils; crested and parakeet auklet, pigeon guillemot, and black-legged kittiwake also nest on the island.[9] Captain Henry James Snow reported that in 1883 some 15,000 northern fur seals inhabited the island. However, by the 1890s only "a few scores" were recorded captured there, almost certainly due to overexploitation by fur hunters. Currently no fur seals reproduce on Raikoke.

Raikoke Island as seen from the Golovnin Strait

History

[edit]

Raikoke was visited by hunting and fishing parties of the Ainu, but there was no permanent habitation at the time of European contact. The island appears on an official map showing the territories of Matsumae Domain, a feudal domain of Edo Japan dated 1644, and these holdings were officially confirmed by the Tokugawa shogunate in 1715. It was subsequently claimed by the Russian Empire; sovereignty initially passed to Russia under the terms of the Treaty of Shimoda, but was returned to the Empire of Japan per the Treaty of Saint Petersburg along with the rest of the Kuril islands.

The island was formerly administered as part of Shimushu District of Nemuro Subprefecture of Hokkaidō. After World War II, it came under the control of the Soviet Union, and is now administered as part of the Sakhalin Oblast of Russia.

See also

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Notes

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References

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Further reading

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[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Raikoke

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from Grokipedia
Raikoke is a small, barren volcanic island in the central archipelago, situated in Russia's within the northwest Pacific Ocean's . The island, measuring approximately 2 by 2.5 kilometers, is dominated by a low, truncated basaltic featuring a 700-meter-wide and 200-meter-deep summit crater with steep walls. The , largely dormant since its last recorded activity in , underwent a brief yet highly on 21–22 June 2019, marking one of the most significant volcanic events in the region during recent decades. This event generated ash plumes rising to 10–12 kilometers above , accompanied by substantial emissions that penetrated the and dispersed globally. The eruption's intensity, estimated at a (VEI) of 4, blanketed the in ash and produced vigorous plumes visible from , with mass eruption rates reaching 1.5–2 × 10^6 kg/s during peak phases. Unmonitored prior to the event, Raikoke's activity provided valuable data for studying stratospheric dispersion and its climatic implications through and modeling.

Geography

Location and regional setting

Raikoke is situated at approximately 48.29°N 153.25°E in the central Kuril Islands archipelago, within the Sea of Okhotsk in the northwest Pacific Ocean. The island lies about 400 km southwest of the southern tip of Russia's Kamchatka Peninsula, forming part of the Greater Kuril Chain that extends roughly 1,200 km from Kamchatka to Hokkaido. This remote, uninhabited location results from its isolation amid the archipelago and recurrent volcanic hazards, with the nearest human settlements on other Kuril Islands such as Paramushir. The Kuril Islands arc, including Raikoke, arises from the active subduction zone where the Pacific Plate descends beneath the Okhotsk microplate at rates of several centimeters per year, generating the compressive forces and magma production that sustain the chain's volcanism. This process exemplifies the causal mechanics of convergent plate boundaries within the Pacific Ring of Fire, where oceanic lithosphere recycling drives arc magmatism through flux melting in the mantle wedge.

Physical characteristics of the island

Raikoke comprises an oval-shaped basaltic island approximately 2 km by 2.5 km in extent, rising above a submarine terrace in the central Kuril Islands. The island's summit reaches an elevation of 551 m above sea level, forming the subaerial portion of a stratovolcano with a base measuring roughly 2.7 km by 2.6 km. A prominent central crater, approximately 700 m wide and 200 m deep, dominates the landscape with steep walls. The flanks feature steep basaltic cliffs and exposures of lava flows, particularly extending along the eastern sector of the island.

Geology

Volcanic structure and stratigraphy

Raikoke exhibits the classic of a , with its edifice constructed through the progressive layering of effusive and explosive products over time. The volcano forms a truncated on a small, barren approximately 2 by 2.5 kilometers in extent, rising about 550 meters above , with a submarine terrace at roughly 130 meters depth marking the base of the subaerial structure. The slopes display alternating sequences of lava flows and pyroclastic deposits, reflecting repeated cycles of magmatic ascent, eruption, and consolidation that build the composite edifice characteristic of convergent margin . The summit is dominated by a steep-walled measuring approximately 700 meters in width and 200 meters in depth, which truncates the upper portion of the cone and exposes older internal layers. lava flows particularly mantle the eastern flank, contributing to an asymmetric profile where effusive activity has partially rebuilt sectors following prior collapses or erosional downcutting. These flows interbed with and fragmental units, forming a stratigraphic record of episodic emplacement without evidence of large-scale sector collapse in the preserved edifice. Stratigraphic exposures on the unvegetated slopes reveal the causal buildup from gravitational settling of ballistic , pyroclastic currents, and subsequent lava overflow, yielding a resilient yet steep-sided form prone to explosive reactivation. Limited direct sampling due to remoteness constrains detailed unit correlations, but the visible layering underscores a history of volatile-driven fragmentation interspersed with degassed , absent pervasive alteration indicative of prolonged hydrothermal activity.

Magma composition and tectonic context

Raikoke volcano lies within the Kuril-Kamchatka island arc system, where the Pacific Plate subducts obliquely beneath the Okhotsk Plate at a convergence rate of approximately 8 cm per year. This rapid subduction releases hydrous fluids from the dehydrating oceanic slab into the overlying mantle wedge, inducing flux melting and generating primary magmas at depths near the Moho (~26 km). The tectonic regime sustains a steady magma supply through adiabatic decompression and volatile addition, characteristic of convergent margin volcanism in the region. Petrological evidence indicates that Raikoke's s are predominantly basaltic-andesitic in bulk composition, derived from of peridotitic sources modified by slab-derived components. Major element analyses of pyroclastic materials show evolved glass phases with silica contents corresponding to andesite-trachyandesite (SiO₂ ~57-63 wt%) and dacite-trachydacite (SiO₂ >63 wt%), reflecting differentiation via in upper crustal reservoirs. Mineral assemblages dominated by , , and further support a hydrous, calc-alkaline series typical of arc settings, with water contents exceeding 4 wt% at depth contributing to . Geochemical profiles exhibit island arc signatures, including enrichments in fluid-mobile large-ion lithophile elements (LILE) such as Ba, U, and Pb relative to high field strength elements (HFSE) like Nb and Ta, attributable to slab fluid fluxing. Sr-Nd-Pb isotopic ratios in Kuril arc lavas, analogous to Raikoke's mantle-derived melts, display trends of decreasing ⁸⁷Sr/⁸⁶Sr and increasing ¹⁴³Nd/¹⁴⁴Nd from the volcanic front rearward, indicating variable contributions from sediment melt and altered oceanic crust in the subducting slab. These empirical patterns underscore causal fluid-mediated metasomatism over bulk slab melting as the primary magma genesis mechanism.

Eruption History

Pre-modern eruptions

Historical records indicate a small at Raikoke around ± 5 years, classified with a (VEI) of 2. Contemporary observations documented an explosion but provided no details on volume, plume height, or associated impacts such as falls. This event represents the earliest confirmed activity in the 's , preceding the more destructive eruption by approximately a decade. Geological investigations have not identified distinct layers attributable to the event in regional sediment cores, limiting reconstructions of its magnitude or precursors to historical accounts alone. Earlier activity, while implied by the 's stratovolcanic structure, lacks specific dating or proxy evidence tied to Raikoke, with tephrostratigraphic studies in the focusing primarily on larger regional events.

1778 eruption

The 1778 eruption of produced explosive and effusive activity rated at (VEI) 4, marking it as one of the most intense historical events at the site prior to the . This event involved the sudden release of magmatic pressure through volatile exsolution, leading to violent fragmentation of ascending and the ejection of pyroclasts. Geological evidence, including remnant layers and altered summit morphology, indicates widespread deposition of ballistic and finer ash across the island's upper slopes, which destroyed much of the pre-eruption vegetation and reshaped the volcanic edifice by excavating a significant portion of the cone's apex. Historical records, derived from contemporary maritime observations, describe ash plumes rising to several kilometers altitude, accompanied by incandescent ejecta that posed hazards to regional shipping. Fifteen fatalities occurred when lava bombs—large, molten pyroclasts—struck a vessel passing near the island, highlighting the eruption's ballistic reach extending beyond the shoreline. No direct accounts confirm pyroclastic flows, but the scale of devastation suggests localized hot avalanches may have scoured flanks, consistent with VEI 4 dynamics in similar stratovolcanoes where rapid decompression drives density currents. The eruption's remnants, observable in the island's steep-walled (approximately 700 m wide and 200 m deep), reflect caldera-like collapse or explosive breaching that defined much of the modern topographic form. Effusive phases produced lava flows along the eastern island margin, interbedded with fall deposits, as evidenced by field surveys linking these units to 18th-century activity. This event spurred the earliest documented volcanological investigations in the Kuril arc, with reports emphasizing the hail of bombs as a key destructive mechanism. Overall, while lacking precise plume height measurements due to observational limits, the eruption's intensity aligns with empirical thresholds for sub-Plinian explosivity, driven by vesiculation in andesitic under arc-typical volatile saturation.

1924 eruption

The 1924 eruption of , the most recent prior to 2019, occurred in mid-February and was classified as (VEI) 4, indicating a significant explosive event with volumes on the order of 0.1–1 cubic kilometer. This activity followed approximately 146 years of quiescence since the 1778 eruption, underscoring the episodic character of volcanism in the Kuril arc where long repose periods precede major releases of accumulated magmatic pressure. Russian observational records from the era, limited by the island's extreme remoteness in the northwest Pacific, primarily noted explosive phases that deepened the summit crater substantially and altered the island's coastline through pyroclastic and effusive deposits. Geological evidence from post-eruption surveys confirms the emission of fresh lava flows that contributed to minor expansion of the island's perimeter, alongside widespread fallout confined to regional scales without documented stratospheric injection. The event was accompanied by eruptive activity in the vicinity of nearby Matua Island, suggesting possible lateral propagation or triggered seafloor venting, though details remain sparse due to observational constraints at the time. Overall, the 1924 eruption exemplifies moderate-to-large arc driven by subduction-related , with structural changes to the edifice persisting into modern assessments.

2019 Eruption

Onset and sequence of events

The 2019 eruption of Raikoke initiated on 21 June at 18:05 UTC with a powerful explosive event, following 95 years of dormancy, and consisted of a short-lived series of large explosions extending through 23 June. Lacking ground-based monitoring stations on the remote island, no real-time seismic precursors were detected; retrospective satellite analyses, including TROPOMI measurements of SO₂ from 15–20 June, revealed no pre-eruptive gas emissions or thermal anomalies attributable to volcanic unrest. The onset featured an initial pulse at approximately 17:50 UTC on 21 June, escalating into at least nine discrete explosions—six clustered within the first 25 minutes—captured by satellite infrared and visible imagery. This activity persisted until about 05:40 UTC on 22 June, corresponding to 19:00 local time on 22 June, with the main Plinian phase commencing at 22:29 UTC on 21 June and enduring roughly 3.5 hours of intense, sustained venting. MODIS and Himawari satellite observations empirically confirmed the progression of these explosive pulses through detected thermal signatures and plume development during peak output. Eruptive vigor waned after the primary explosive sequence, with intermittent gas-and-steam emissions and minor ash venting reported until 23 June, signaling the end of the brief but vigorous phase. By 25 June, activity had subsided to low-level plumes rising up to 2 km, as observed via satellite.

Plume dynamics and ejecta characteristics

The 2019 eruption of Raikoke produced a highly dynamic and gas plume that rose rapidly to altitudes of 13–14 km above , as observed by sounders and plume modeling. This height reflects the eruption's transition into a buoyant convective , where the plume's overcame atmospheric stratification, enabling sustained ascent despite entrainment of ambient air. The plume exhibited pulsatory behavior over approximately 16 hours, consisting of at least 11 distinct eruptive pulses, each contributing to vertical development and associated with generation within the plume column. Formation of an umbrella cloud at the plume top, evident in approximately 150 km downwind, signified high explosivity and lateral spreading driven by momentum and buoyancy balance, with the cloud's expansion correlating positively with the spatial extent of activity. This structure arose from the collapse and radial outflow of the plume head upon reaching levels in the , a process modeled through one-dimensional simulations confirming maximum pulse heights of 9–16.5 km capable of producing such features. The dynamics were primarily propelled by volatile exsolution—rapid of , , and other gases from ascending —generating overpressure that fragmented material and sustained without reliance on external for initial rise. Ejecta characteristics featured a dominance of fine ash particles, with modal sizes in the sub-micrometer to tens of micrometers range, comprising very fine fractions (e.g., 0.4–1.8 Tg total fine ash mass) that resisted gravitational settling and enabled stratospheric injection. Particle size distributions, informed by dispersion models and comparisons to analogous eruptions, showed a log-normal profile skewed toward smaller diameters, with effective densities reduced by vesicularity and irregular shapes enhancing aerodynamic suspension. Coarser ballistic ejecta, including lapilli-sized fragments, were confined to the island's vicinity, depositing as proximal fallout and covering the terrain in thick ash layers up to several centimeters, while minimal large blocks indicate fragmentation efficiency favored fines over massive ejecta.

Emission volumes and eruption metrics

The 2019 eruption of Raikoke volcano achieved a Volcanic Explosivity Index (VEI) of 4, determined from satellite-derived minimum tephra volumes exceeding 0.1 km³, corresponding to dense rock equivalent (DRE) ejecta estimates of approximately 0.1–0.4 km³. This classification reflects the eruption's capacity to eject significant pyroclastic material, with ash masses ranging from 0.4 to 1.8 × 10⁹ kg based on plume height correlations and dispersion modeling. Sulfur dioxide emissions totaled around 1.5 ± 0.2 Tg, representing the largest stratospheric SO₂ injection from a single eruption since the 2011 Nabro event. These quantities were quantified through UV retrievals from instruments such as TROPOMI and OMPS, which tracked the initial plume dispersal eastward. The ash plume attained heights of 17–19 km, enabling stratospheric penetration confirmed by lidar profiles detecting aerosol layers above the tropopause. While much of the coarser ash settled locally, finer fractions dispersed globally, with integrated analyses correcting initial underestimations in plume mass loading by factors of up to 20–50% through multi-sensor fusion and trajectory modeling.

Impacts

Local terrain and ecological alterations

The 2019 eruption of significantly altered the island's local terrain, with revealing an expanded rim and increased island surface area due to pyroclastic flows and debris deposits at the slopes' bases. These flows displaced the shoreline seaward, extending the island's footprint through accumulation of volcanic material. Pre-eruption images depicted vegetated slopes, which post-eruption appeared blanketed in ash and , indicating widespread destruction of upper slope vegetation. Ecological shifts were evident in the immediate aftermath, including a possible algal bloom south of the island, potentially linked to nutrient runoff from ash-laden debris entering surrounding waters. The uninhabited status of Raikoke precluded human casualties, allowing natural processes to dominate recovery dynamics without anthropogenic interference. Volcanic deposits covered former biotic zones, burying soils and under meters of in some areas, though marine ecosystems adjacent to the may have experienced localized enrichment from solubilized minerals.

Stratospheric and global atmospheric effects


The 2019 Raikoke eruption injected approximately 1.5 ± 0.2 teragrams of sulfur dioxide (SO₂) into the stratosphere, the largest such emission since the 2011 Nabro eruption, alongside ash particles that reached altitudes exceeding 20 km. This led to the rapid conversion of SO₂ into sulfate aerosols through gas-to-particle processes, forming a persistent layer primarily in the Northern Hemisphere lower stratosphere. The plumes dispersed globally via stratospheric circulation, with satellite observations tracking SO₂ and aerosol clouds circling the planet, though concentrations were highest in northern latitudes due to poleward transport. Sulfate aerosols scattered incoming solar radiation, resulting in a minor temporary global surface cooling of approximately 0.02°C observed in 2020, negligible compared to anthropogenic warming trends. SO₂ concentrations declined with an time of 8–18 days, while s persisted for months, detectable by multiple instruments including CALIOP and OMPS. Peak aerosol optical depths occurred over regions, where a long-lived anticyclone confined portions of the plume, enhancing local before dissipation. Heterogeneous chemical reactions on volcanic surfaces catalyzed , with ground-based observations over eastern recording a sharp reduction of up to 73 Dobson units (DU) shortly after the eruption's cessation on , 2019. This localized effect stemmed from enhanced activation and loss cycles, akin to processes in polar stratospheric clouds, though confined to mid-to-high latitudes impacted by the plume. Overall atmospheric perturbations, including burdens and anomalies, subsided within 1–2 years, as evidenced by profiles and ozonesonde measurements showing return to baseline stratospheric conditions by late 2020. Exaggerated projections of prolonged disruption overlook the eruption's modest scale relative to events like Pinatubo, with empirical data confirming short-lived influences absent sustained forcing.

Long-term monitoring and research findings

Following the 2019 eruption, Raikoke has exhibited no signs of renewed volcanic activity through October 2025, as documented by continuous satellite-based observations from the Smithsonian Institution's (GVP) and Russian seismic networks in the Kuril region. These efforts rely primarily on via instruments such as MODIS, TROPOMI, and , which detect thermal anomalies, gas emissions, and plume signatures but are limited by the volcano's remote, uninhabited location and lack of on-site instrumentation, potentially missing low-level unrest. Post-eruption research has validated plume evolution models through empirical data, with studies tracking stratospheric dispersal and persistence for months after . A 2023 analysis using ground-based in , , observed Raikoke-derived layers at altitudes of 15-25 km in the mid-latitudes, confirming transport pathways and rates predicted by dispersion simulations. Similarly, a 2024 peer-reviewed assessment by the Volcano Response group utilized the eruption as a benchmark for rapid atmospheric impact evaluation, quantifying conversion to s and their radiative effects via multi-satellite datasets, which aligned with pre-eruption model forecasts without invoking unsubstantiated eruption triggers. These findings underscore the value of integrated remote datasets for forecasting plume trajectories and aerosol lifetimes, yet highlight inherent gaps in , such as underestimation of fine fractions and real-time plume height variability due to cloud interference and sensor resolution limits. Ongoing GVP bulletins emphasize evidence-based projections, prioritizing observed quiescence and historical repose intervals over probabilistic models lacking direct precursors, to inform and regional risk assessments without overreliance on unverified geophysical speculations.

Ecology

Pre-eruption biodiversity

Prior to the 2019 eruption, Raikoke Island supported and covering approximately 60% of its surface, primarily on the slopes and inner walls, with from early June 2019 indicating heavy across most areas. Expeditions in 1996 and 2000 documented 68 of vascular plants, including grasses adapted to nutrient-poor volcanic soils, sedges, and low shrubs such as Salix reiniana and Spiraea betulifolia, but no endemic were identified. Lichens and mosses formed pioneer communities on recent ash deposits, reflecting the island's history of periodic volcanic disturbances, including the 1924 eruption, which limited overall plant diversity and biomass accumulation through recurrent burial and soil sterilization. Avifauna on Raikoke consisted mainly of seabirds utilizing cliff faces and coastal areas for nesting, with species typical of the central Kuril Islands such as storm petrels (Hydrobates spp.) and shearwaters (Puffinus spp.) documented in regional surveys, though island-specific censuses were limited due to its remoteness. Marine mammals, including northern fur seals (Callorhinus ursinus) and Steller sea lions (Eumetopias jubatus), periodically hauled out on the island's shores for breeding and resting, contributing to nutrient cycling via guano deposition that supported localized plant growth. The absence of terrestrial mammals and low arthropod diversity underscored the ecosystem's reliance on marine subsidies and its vulnerability to eruptive resets, as frequent volcanism prevented succession to more complex communities.

Post-2019 recovery and changes

Following the 2019 eruption, Raikoke Island was initially covered in a thick layer of pyroclastic deposits, rendering much of the surface barren and inhibiting immediate vegetation regrowth. from late June 2019 captured pale blanketing formerly vegetated areas, with steam and gas emissions persisting along the shoreline. Analysis of (NDVI) time series post-eruption indicates minimal recovery in terrestrial vegetation, with projections estimating approximately 100 years for substantial regrowth due to the depth and composition of layers. processes are expected to facilitate gradual succession by exposing underlying substrates and distributing nutrients, potentially enabling colonization, though empirical ground-truth data remains sparse owing to the island's remote location. Marine ecological responses included a possible south of the island, detectable in post-eruption NDVI imagery as enhanced "vegetation" signals indicative of proliferation. This bloom may stem from nutrient enrichment via ash deposition, including iron and trace elements that alleviate limitations in surrounding waters. The eruption also expanded the island's surface area and enlarged the , alterations that could influence local habitats by creating new substrates for microbial and algal communities without evidence of widespread disruption. Seabird populations, which historically nested on the , showed resilience with no documented mass die-offs attributable to the eruption. Limited monitoring suggest that avian communities may benefit from expanded for breeding sites, though comprehensive surveys are lacking. Succession on Raikoke proceeds via disturbance-driven mechanisms, prioritizing empirical indicators like NDVI over unsubstantiated restoration narratives.

References

  1. https://volcano.si.edu/volcano.cfm?vn=290250
  2. https://www.volcanodiscovery.com/raikoke.html
  3. https://earthobservatory.[nasa](/page/NASA).gov/images/145226/raikoke-erupts
  4. https://www.sciencedirect.com/science/article/abs/pii/S0377027321001839
  5. https://acp.copernicus.org/articles/21/10851/
  6. https://www.researchgate.net/publication/396756389_Transport_of_volcanic_aerosol_from_the_Raikoke_eruption_in_2019_through_the_Northern_Hemisphere
  7. https://acp.copernicus.org/articles/24/5765/2024/acp-24-5765-2024.pdf
  8. http://volcanolive.com/raikoke.html
  9. https://factsanddetails.com/russia/Places/sub9_9e/entry-7103.html
  10. https://www.sciencedirect.com/science/article/am/pii/S0377027321001839
  11. https://volcanohotspot.wordpress.com/2019/07/07/june-22-eruption-at-raikoke-kuril-islands/comment-page-1/
  12. https://www.usgs.gov/media/images/pacific-ocean-subduction-zones
  13. https://science.nasa.gov/photojournal/raikoke-island-kuril-islands/
  14. https://escholarship.org/content/qt24g740rg/qt24g740rg.pdf
  15. http://www.ipgg.sbras.ru/ru/publications/ibc/2021/jvgr-2021-418-107346.pdf
  16. https://agupubs.onlinelibrary.wiley.com/doi/full/10.1029/2019GC008373
  17. https://www.biosoil.ru/Research/Publication/19977
  18. https://agupubs.onlinelibrary.wiley.com/doi/full/10.1029/2019JB019237
  19. https://link.springer.com/article/10.1134/S0869591110050048
  20. https://volcano.oregonstate.edu/raikoke
  21. https://escholarship.org/content/qt24g740rg/qt24g740rg_noSplash_87f947bb2e741ee262f7677a64018e69.pdf
  22. https://volcano.si.edu/showreport.cfm?doi=GVP.WVAR20190619-290250
  23. https://earthobservatory.nasa.gov/images/145226/raikoke-erupts
  24. https://www.jvolcanica.org/ojs/index.php/volcanica/article/view/159
  25. https://acp.copernicus.org/articles/22/3535/2022/
  26. https://www.sciencedirect.com/science/article/pii/S037702732500040X
  27. https://acp.copernicus.org/articles/22/2975/2022/
  28. https://acp.copernicus.org/articles/24/5765/2024/
  29. https://ui.adsabs.harvard.edu/abs/2021EGUGA..23.9174B/abstract
  30. https://digitalcommons.mtu.edu/michigantech-p2/746/
  31. https://ntrs.nasa.gov/citations/20200003764
  32. https://agupubs.onlinelibrary.wiley.com/doi/10.1029/2022JD038080
  33. https://www.usgs.gov/publications/evaluating-state-art-remote-volcanic-eruption-characterization-part-i-raikoke-volcano
  34. https://agupubs.onlinelibrary.wiley.com/doi/abs/10.1029/2022JD036600
  35. https://ntrs.nasa.gov/api/citations/20220007843/downloads/Accepted%2520Manuscript%2520-%2520Gorkavyi_Krotkov%2520-%2520Tracking%2520aerosols%2520and%2520SO2%2520clouds%2520from%2520the%2520Raikoke%2520-%2520AMT%25202021.pdf
  36. https://d-nb.info/1230557237/34
  37. https://egusphere.copernicus.org/preprints/2023/egusphere-2023-1116/
  38. https://amt.copernicus.org/articles/14/7545/2021/
  39. https://www.nature.com/articles/s41598-022-27021-0
  40. https://ui.adsabs.harvard.edu/abs/2024IzAOP..60.1536B/abstract
  41. https://www.sciencedirect.com/science/article/abs/pii/S1352231023003060
  42. https://www.volcanodiscovery.com/raikoke-earthquakes/archive/2025-jan.html
  43. https://carnegiescience.edu/evaluating-state-art-remote-volcanic-eruption-characterization-part-i-raikoke-volcano-kuril-islands
  44. https://link.springer.com/article/10.1134/S074204632105002X
  45. http://kurilskiy.ru/kurilskiy-fauna-en
  46. https://www.researchgate.net/publication/357636918_The_2019_Explosive_Eruption_of_Raikoke_Volcanic_Island_Kuriles_Pyroclastic_Deposits_and_Their_Impact_on_the_Relief_and_Ecosystems
  47. https://core.ac.uk/download/565830524.pdf
  48. https://laro.lanl.gov/view/pdfCoverPage?instCode=01LANL_INST&filePid=13158283900003761&download=true
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