Timeline of volcanism on Earth

2011 Puyehue-Cordón Caulle eruption 1980 eruption of Mount St. Helens 1912 eruption of Novarupta Yellowstone Caldera AD 79 Eruption of Mount Vesuvius 1092 eruption of Santa María 1280 eruption of Quilotoa 1600 eruption of Huaynaputina 2010 eruptions of Eyjafjallajökull Yellowstone Caldera 1783 eruption of Laki 1477 eruption of Bárðarbunga 1650 eruption of Kolumbo Volcanic activity at Santorini Toba catastrophe theory Kuril Islands Baekdu Mountain Kikai Caldera 1991 eruption of Mount Pinatubo Long Island (Papua New Guinea) 1815 eruption of Mount Tambora 1883 eruption of Krakatoa 2010 eruptions of Mount Merapi Billy Mitchell (volcano) Taupo Volcano Taupo Volcano Taupo Volcano Crater Lake
Clickable imagemap of notable volcanic eruptions. The apparent volume of each bubble is linearly proportional to the volume of tephra ejected, colour-coded by time of eruption as in the legend. Pink lines denote convergent boundaries, blue lines denote divergent boundaries and yellow spots denote hotspots.

This timeline of volcanism on Earth is a list of major volcanic eruptions of approximately at least magnitude 6 on the Volcanic Explosivity Index (VEI) or equivalent sulfur dioxide emission around the Quaternary period. Some cooled the global climate; the extent of this effect depends on the amount of sulfur dioxide emitted.[1][2] The topic in the background is an overview of the VEI and sulfur dioxide emission/ Volcanic winter relationship. Before the Holocene epoch the criteria are less strict because of scarce data availability, partly since later eruptions have destroyed the evidence. So, the known large eruptions after the Paleogene period are listed, and especially those relating to the Yellowstone hotspot, the Santorini, and the Taupo Volcanic Zone. Only some eruptions before the Neogene period are listed. Active volcanoes such as Stromboli, Mount Etna and Kilauea do not appear on this list, but some back-arc basin volcanoes that generated calderas do appear. Some dangerous volcanoes in "populated areas" appear many times: so Santorini, six times and Yellowstone hotspot, twenty-one times. The Bismarck volcanic arc, New Britain and the Taupo Volcanic Zone, New Zealand appear often too.

In order to keep the list manageable, the eruptions in the Holocene on the link: Holocene Volcanoes in Kamchatka aren't yet added, but they are listed in Peter L. Ward's supplemental table.[3]

Large Quaternary eruptions

The Holocene epoch begins 11,700 years BP[4] (10,000 14C years ago).

Since 1000 AD

Overview of Common Era

This is a sortable summary of major eruptions over the last 2000 years with VEI 6+ (but including the notable VEI 5 eruptions of Mount St. Helens, Mount Tarawera and Mount Vesuvius). Date uncertainties, tephra volumes, and references are not included.

Caldera/ Eruption nameVolcanic arc/ belt
or Subregion or Hotspot
VEIDateKnown/proposed consequences
Mount PinatuboLuzon Volcanic Arc61991, Jun 15 Global temperature fell by 0.4 °C
Mount St. HelensCascade Volcanic Arc51980, May 18
NovaruptaAleutian Range61912, Jun 6
Santa MaríaCentral America Volcanic Arc61902, Oct 24
Mount TaraweraTaupo Volcanic Zone51886, Jun-AugDestruction of the Pink and White Terraces, which were nicknamed the '8th wonder of the natural world'.
KrakatoaSunda Arc61883, Aug 26–27At least 30,000 dead
Mount TamboraLesser Sunda Islands71815, Apr 10Year Without a Summer (1816)
Grímsvötn and LakiIceland61783-85Mist Hardships
Long Island (Papua New Guinea)Bismarck Volcanic Arc61660
Kolumbo, SantoriniSouth Aegean Volcanic Arc51650, Sep 27
HuaynaputinaAndes, Central Volcanic Zone61600, Feb 19Russian famine of 1601–1603
Billy MitchellBougainville & Solomon Is.61580
BárðarbungaIceland61477
KuwaeNew Hebrides Arc61452-532nd pulse[21] of Little Ice Age?
QuilotoaAndes, Northern Volcanic Zone61280
Samalas (Mount Rinjani)Lombok, Lesser Sunda Islands612571st pulse[22][23] of Little Ice Age? (c.1250)
Baekdu Mountain/Tianchi eruptionChina/ North Korea border7946, Nov-947 Limited regional climatic effects.[24]
Katla/Eldgjá eruptionIceland6934-940
CeborucoTrans-Mexican Volcanic Belt6930
DakatauaBismarck Volcanic Arc6800
PagoBismarck Volcanic Arc6710
Mount Churchilleastern Alaska, USA6700
Rabaul CalderaBismarck Volcanic Arc6540 (est.)Extreme weather events of 535–536
IlopangoCentral America Volcanic Arc6450
KsudachKamchatka Peninsula6240
Taupo Caldera/Hatepe eruptionTaupo Volcano7180 or 230Affected skies over Rome and China
Mount Vesuvius/Pompeii eruptionItaly579
Mount Churchilleastern Alaska, USA660
AmbrymNew Hebrides Arc650
ApoyequeCentral America Volcanic Arc 650 BC

Note: Caldera names tend to change over time. For example, Okataina Caldera, Haroharo Caldera, Haroharo volcanic complex, Tarawera volcanic complex had the same magma source in the Taupo Volcanic Zone. Yellowstone Caldera, Henry's Fork Caldera, Island Park Caldera, Heise Volcanic Field had all Yellowstone hotspot as magma source.

Earlier Quaternary eruptions

2.588 ± 0.005 million years BP, the Quaternary period and Pleistocene epoch begin.

Large Neogene eruptions

Pliocene eruptions

Approximately 5.332 million years BP, the Pliocene epoch begins. Most eruptions before the Quaternary period have an unknown VEI.

Santa Rosa-Calico
Virgin Valley
McDermitt
Black Mountain
Silent Canyon
Timber Mountain
Stonewall
Long Valley
Lunar Crater
Nevada/ California:
Volcanism locations.
Cochetopa
La Garita
Lake City
Platoro
Dotsero
Colorado volcanism. Links: La Garita, Cochetopa and North Pass (North Pass), Lake City, and Dotsero.
Valles
Socorro
Potrillo
Zuni-Bandera
Carizzozo
New Mexico volcanism. Links: Valles, Socorro, Potrillo, Carrizozo, and Zuni-Bandera.

Miocene eruptions

Approximately 23.03 million years BP, the Neogene period and Miocene epoch begin.

Volcanism before the Neogene

Distribution of selected hotspots. The numbers in the figure are related to the listed hotspots on Hotspot (geology).

Notes

Volcanic Explosivity Index (VEI)

VEI and ejecta volume correlation
VEI Tephra Volume
(cubic kilometers)
Example
0 Effusive Masaya Volcano, Nicaragua, 1570
1 >0.00001 Poás Volcano, Costa Rica, 1991
2 >0.001 Mount Ruapehu, New Zealand, 1971
3 >0.01 Nevado del Ruiz, Colombia, 1985
4 >0.1 Eyjafjallajökull, Iceland, 2010
5 >1 Mount St. Helens, United States, 1980
6 >10 Krakatoa, Indonesia, 1883
7 >100 Mount Tambora, Indonesia, 1815
8 >1000 Yellowstone Caldera, United States, Pleistocene

       

Volcanic dimming

Main article: Global dimming

The global dimming through volcanism (ash aerosol and sulfur dioxide) is quite independent of the eruption VEI.[92][93][94] When sulfur dioxide (boiling point at standard state: -10 °C) reacts with water vapor, it creates sulfate ions (the precursors to sulfuric acid), which are very reflective; ash aerosol on the other hand absorbs Ultraviolet.[95] Global cooling through volcanism is the sum of the influence of the global dimming and the influence of the high albedo of the deposited ash layer.[96] The lower snow line and its higher albedo might prolong this cooling period.[97] Bipolar comparison showed six sulfate events: Tambora (1815), Cosigüina (1835), Krakatoa (1883), Agung (1963), and El Chichón (1982), and the 1809–10 ice core event.[98] And the atmospheric transmission of direct solar radiation data from the Mauna Loa Observatory (MLO), Hawaii (19°32'N) detected only five eruptions:[99]

 

But very large sulfur dioxide emissions overdrive the oxidizing capacity of the atmosphere. Carbon monoxide's and methane's concentration goes up (greenhouse gases), global temperature goes up, ocean's temperature goes up, and ocean's carbon dioxide solubility goes down.[2]

Map gallery

  1. ^ Cite error: The named reference malheurrivergorge was invoked but never defined (see the help page).

See also

References

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