Novarupta 1912/6
Start: June 6, 1912 [1]
Stop: June 9, 1912 [1]
Event Type: Explosive
Max VEI: 6 [2]
Description: Fierstein and Hildreth (2001) provide information about the magitude of the 1912 eruption at Novarupta and Katmai: "The world's largest volcanic eruption of the 20th century broke out at Novarupta [see fig. 1 in original text] in June 1912, filling with hot ash what came to be called the Valley of Ten Thousand Smokes and spreading downwind more fallout than all other historical Alaskan eruptions combined. Although almost all the magma vented at Novarupta, most of it had been stored beneath Mount Katmai 10 km away, which collapsed during the eruption. Airborne ash from the 3-day event blanketed all of southern Alaska, and its gritty fallout was reported as far away as Dawson, Ketchikan, and Puget Sound [see fig. 21 in original text]. Volcanic dust and sulfurous aerosol were detected within days over Wisconsin and Virginia; within 2 weeks over California, Europe, and North Africa; and in latter-day ice cores recently drilled on the Greenland ice cap."
Schaaf (2004) contains excerpts and summaries of eyewitness accounts of the eruption; a copy of this publication is available online at https://www.nps.gov/articles/aps-v11-i1-c9.htm. Detailed, firsthand narratives of the events as experienced at Kodiak are given in Perry, 1914, and Erskine, 1962.
Hildreth and Fierstein also published a free download tome of information about this eruption: https://pubs.usgs.gov/pp/1791/
From Fierstein and others (1998): "On the afternoon of June 6, 1912, an ominous cloud rose into the sky above Mount Katmai on the Alaska Peninsula. The cloud quickly reached an altitude of 20 miles, and within 4 hours, ash from a huge volcanic eruption began to fall on the village of Kodiak, 100 miles to the southeast. By the end of the eruption on June 9th, the ash cloud, now thousands of miles across, shrouded southern Alaska and western Canada, and sulfurous ash was falling on Vancouver, British Columbia, and Seattle, Washington. The next day the cloud passed over Virginia, and by June 17th it reached Algeria in Africa.
"During the 3 days of the eruption, darkness and suffocating conditions caused by falling ash and sulfur dioxide gas immobilized the population of Kodiak. Sore eyes and respiratory distress were rampant, and water became undrinkable. Radio communications were totally disrupted, and with visibility near zero, ships couldn't dock. Roofs in Kodiak collapsed under the weight of more than a foot of ash, buildings were wrecked by ash avalanches that rushed down from nearby hillslopes, and other structures burned after being struck by lightning from the ash cloud.
"Similar conditions prevailed elsewhere in southern Alaska, and several villages were abandoned forever. Animal and plant life was decimated by ash and acid rain from the eruption. Bears and other large animals were blinded by ash and starved when large numbers of the plants and small animals they lived on were wiped out. Millions of dead birds that had been blinded and coated by volcanic ash littered the ground. Aquatic organisms, such as mussels, insect larvae, and kelp, as well as the fish that fed upon them, perished in ash-choked shallow water. Alaska's salmon-fishing industry was devastated, especially from 1915 to 1919, because of the starvation and failure of many adult fish to spawn in ash-choked streams.
"In 1916, a National Geographic Society expedition led by Robert Griggs visited Mount Katmai and found a 2-mile-wide crater where its summit had been before 1912. Nearby, the expedition discovered a newly formed lava dome they called 'Novarupta' and huge flows of volcanic ash filling what they named the 'Valley of Ten Thousand Smokes' for the numerous plumes of steam rising from the still hot ground. Griggs' descriptions of these spectacular features helped persuade President Woodrow Wilson to create Katmai National Monument (now National Park) in 1918.
"In the 1950's, volcanologists discovered that the 1912 eruption was actually from Novarupta, not Mount Katmai. Novarupta's eruption had removed so much molten rock (magma) from beneath Mount Katmai that it caused a cubic mile of Katmai's summit to collapse."
Hildreth (1983) gives the following detailed description of the events of the eruption: "Because there were no geophysical instruments in Alaska, no scientfic observers in the district, and no eyewitnesses with a view of the VTTS [Valley of Ten Thousand Smokes], most reports of seismic, acoustic, and eruptive phenomena were not necessarily very accurate, chronologically or descriptively. The most reliable data are the visual observations from aboard the steamer Dora and the record of tephra falls at Kodiak [see figs. 1, 4, in original text] (Martin, 1913; Griggs, 1922). Martin visited Kodiak, Uyak, Katmai village, and Cold Bay [see fig. 1 in original text] in August of 1912 and gathered what accounts he could from residents of the district, but he did not venture inland to the volcanoes nor was he able to interview anyone from the two bands of native hunter-fishermen said to have been within 30 and 40 km, respectively, north and south of Novarupta at the time of the initial outburst. Reconstructions of the eruptive sequence by Griggs (1922) and Fenner (1923, 1925, 1950) are heavily inferential, overinterpretive both of Martin's data and of latter-day interviews with people said to have been at Savonoski when the eruption began (see below), and suffer badly from the incorrect assumption that much of the tephra had come from Mt. Katmai. The following is a critical reappraisal of what appear to be the facts, as assembled largely by G.C. Martin (1913; and unpublished USGS field notes); all times cited are adjusted to Alaskan local time.
"Earthquakes were reported to have been felt at Katmai village (30 km SSE of Novarupta) as early as the evening of 31 May, and severe shocks were felt at Uyak, Kanatak, and Nushugak (200 km WNW) on 4 and 5 June. On the morning of 6 June, explosions were heard at Nushugak and at Seldovia (240 km ENE) but there were no reports of accompanying seismicity or ash clouds. The same morning the Dora left Uyak at 0845 and steamed north-eastward up Shelikof Strait, the Katmai-group volcanoes in full view with a 'strong westerly breeze and fine clear weather,' but no one aboard noticed a tephra column until 1300 (when the vessel was ~88 km southeast of Novarupta). That column was clearly Plinian and, as shown below by the stratigraphic data, it was predominantly rhyolitic; the cloud overtook the Dora by 1500 and began dropping ash at Kodiak (170 km ESE) [see figs. 1, 4, in original text] by 1700.
"Separate interviews with two individuals said to have been in or near Savonoski (30 km N) on the morning of 6 June were conducted in 1918 (Griggs, 1922, p. 17) and in 1923 (Fenner, 1925, p. 216); these have been interpreted to suggest that the ash flow in the VTTS began in the morning several hours prior to the first high tephra column. This is quite unlikely in view of: (1) the record of the Dora; (2) the fact that the basal tephra layer in the VTTS, the distinctively rhyolitic Layer A, does not occur atop the ash-flow deposit; and (3) the common association of pumiceous pyroclastic flows with the collapse of vertical eruption columns. Preliminary eruptive activity at Novarupta on the morning of 6 June is quite reasonable and may be the best explanation of the noise and dust reported that morning at Savonoski and the explosions heard at Nushugak and Seldovia; but a major eruption column and a rhyolitic ash flow several km^3 in volume are certainly excluded prior to 1300.
"Major shocks that punctuated virtually continuous seismic activity were reported locally at ~1300 and ~2300 on 6 June and ~2240 on 7 June. These times are not necessarily very accurate. The first instrumentally recorded teleseism (at Seattle) is reported to have arrived at 1241 on 6 June (Fenner, 1925). Harvard, Ottawa, and several Eurasian stations recorded many teleseisms originating in southwest Alaska between 1805 on 6 June and ~2100 on 11 June. One of these near midnight on 6/7 June has been estimated at magnitude 6.4 and another at 0606 on 10 June at magnitude 7.0 (Coffman and von Hake, 1973). Earthquakes following the main phases of the eruption were felt at Cold Bay (60 km SSW) on 50 of the 70 days through mid-August (Fenner, 1925).
"A great explosion, accompanied by an earthquake felt at Cold Bay ~1300 on 6 June (Martin, 1913), was audible throughout the region and close in time to the first recorded teleseism and to the first sighting of tephra by the Dora. Another blast at ~1500 on 6 June, for which no accompanying earthquake was noted, may have been the most severe outburst of all, being heard for hundreds of kilometers (Martin, 1913). Martin suggested, but did not cite any evidence for, explosions synchronous with the large earthquakes felt nearby at ~2300 on 6 June and 2240 on 7 June. There were, however, reports of loud noises between midnight and 0200 on 8 June, at Katanak (95 km SW) and at Cordova (590 km ENE) (Martin, 1913; Fenner, 1925). Explosions continued to be heard, some as far away as Juneau (1200 km) until 10 June, though how many of the noises may have been thunder is impossible to assess.
"Major tephra eruptions, first noted by the Dora at 1300 on 6 June, continued to fall heavily on downwind settlements nearby until 9 June. The principal sector of dispersal was southeastward [see fig. 1 in original text], and the most distant positive record of ashfall was in Puget Sound (2400 km SE); atmospheric effects were worldwide (Griggs, 1922; Volz, 1975). In the main downwind direction at Kodiak (170 km ESE) there were three discrete periods of ashfall [see fig. 4 in original text]: (1) 1700 6 June until 0910 7 June; (2) ~1200 7 June until 1430 8 June; and (3) during the night of 8/9 June. The 9th of June dawned clear, and no further ash-falls were recorded on Kodiak Island. A major vapor plume and, possibly, sporadic ashfalls close to the source lasted all summer (Martin, 1913; Griggs, 1922; Fenner, 1925). Timing of the emplacement of the Novarupta dome is poorly known; its extrusion followed the last major tephra fall and was complete at the time of discovery on 31 July 1916.
"Details of correlation between audible explosions, tephra falls, and seismic events are not well known. Martin (1913) is the principal source, but his article has been misread and overinterpreted and ensuing errors propagated in successive publications. The seismicity does not correlate very well with eruptive events, and indeed there need be no correspondence (e.g. Filson and others, 1973; Nairn and others, 1976; Yokoyama and others, 1981). Much of the seismic activity seems more likely to have been related to fitful subsidence of Katmai and Novarupta calderas.
"At the onset of eruption, no one is known to have had a view of the VTTS (much less the Novarupta area itself), and only the party of native fishermen then southwest of Katmai village en route to Cold Bay may have been in a position to see Mt. Katmai. The Savonoski interviews (above) smack of ex post facto embellishment, although Martin (1913, p. 147) accepted a third hand report in 1912 that the villagers there may have seen Mt. Katmai after its collapse, but before 9 June. It is not clear where they might have had such a view, because, even notwithstanding the ash clouds, Mt. Katmai is not visible from Savonoski or along their escape route down the lake to Naknek [see fig. 1 in original text]. Martin, Griggs, and Fenner accepted such reports to mean that Mt. Katmai had lost its top by the afternoon of 6 June. This may be true, but it is not clear how Mt. Katmai could have been seen at all during the eruptive interval at Novarupta or what meaning should be attached to such expressions as 'blown off' or 'blown up.' No definitive geologic evidence has been found to fix the timing of Mt. Katmai's collapse, but it may be a reasonable inference that in addition to the syneruptive earthquakes, much of the summer-long seismicity can be attributed to such collapse, as well as to tectonic adjustments over a somewhat wider area, or even to dome emplacement at Novarupta."
Hildreth (1983) also reports that "pumice in the intial fall unit (A) is 100% rhyolite, but fall units atop the ash flow are >98% datcite; black andesitic scoria is common only in the ash flows and in near-vent air-fall tephra." He also states: The Novarupta lava dome is "diameter 380 m, its hieight ~65 m, and the intermediate (mostly dacite) lava interbanded with the rhyolite consitutes no more than 5% of the exposure; most of the conspicuous banding reflects textural variation in the rhyolite."
Fierstein and Hildreth (2001) estimate that the Novarupta eruption of 1912 ejected "at least 17 cubic km of fall deposits and about 11 cubic km of ash-flow tuff (ignimbrite) * * * emplaced in about 60 hours, representing a magma volume of about 13 cubic km (Fierstein and Hildreth, 1992). Hildreth (1987) estimates the volume of the Novarupta lava dome to be 0.005 cubic km.
Schaaf (2004) contains excerpts and summaries of eyewitness accounts of the eruption; a copy of this publication is available online at https://www.nps.gov/articles/aps-v11-i1-c9.htm. Detailed, firsthand narratives of the events as experienced at Kodiak are given in Perry, 1914, and Erskine, 1962.
Hildreth and Fierstein also published a free download tome of information about this eruption: https://pubs.usgs.gov/pp/1791/
From Fierstein and others (1998): "On the afternoon of June 6, 1912, an ominous cloud rose into the sky above Mount Katmai on the Alaska Peninsula. The cloud quickly reached an altitude of 20 miles, and within 4 hours, ash from a huge volcanic eruption began to fall on the village of Kodiak, 100 miles to the southeast. By the end of the eruption on June 9th, the ash cloud, now thousands of miles across, shrouded southern Alaska and western Canada, and sulfurous ash was falling on Vancouver, British Columbia, and Seattle, Washington. The next day the cloud passed over Virginia, and by June 17th it reached Algeria in Africa.
"During the 3 days of the eruption, darkness and suffocating conditions caused by falling ash and sulfur dioxide gas immobilized the population of Kodiak. Sore eyes and respiratory distress were rampant, and water became undrinkable. Radio communications were totally disrupted, and with visibility near zero, ships couldn't dock. Roofs in Kodiak collapsed under the weight of more than a foot of ash, buildings were wrecked by ash avalanches that rushed down from nearby hillslopes, and other structures burned after being struck by lightning from the ash cloud.
"Similar conditions prevailed elsewhere in southern Alaska, and several villages were abandoned forever. Animal and plant life was decimated by ash and acid rain from the eruption. Bears and other large animals were blinded by ash and starved when large numbers of the plants and small animals they lived on were wiped out. Millions of dead birds that had been blinded and coated by volcanic ash littered the ground. Aquatic organisms, such as mussels, insect larvae, and kelp, as well as the fish that fed upon them, perished in ash-choked shallow water. Alaska's salmon-fishing industry was devastated, especially from 1915 to 1919, because of the starvation and failure of many adult fish to spawn in ash-choked streams.
"In 1916, a National Geographic Society expedition led by Robert Griggs visited Mount Katmai and found a 2-mile-wide crater where its summit had been before 1912. Nearby, the expedition discovered a newly formed lava dome they called 'Novarupta' and huge flows of volcanic ash filling what they named the 'Valley of Ten Thousand Smokes' for the numerous plumes of steam rising from the still hot ground. Griggs' descriptions of these spectacular features helped persuade President Woodrow Wilson to create Katmai National Monument (now National Park) in 1918.
"In the 1950's, volcanologists discovered that the 1912 eruption was actually from Novarupta, not Mount Katmai. Novarupta's eruption had removed so much molten rock (magma) from beneath Mount Katmai that it caused a cubic mile of Katmai's summit to collapse."
Hildreth (1983) gives the following detailed description of the events of the eruption: "Because there were no geophysical instruments in Alaska, no scientfic observers in the district, and no eyewitnesses with a view of the VTTS [Valley of Ten Thousand Smokes], most reports of seismic, acoustic, and eruptive phenomena were not necessarily very accurate, chronologically or descriptively. The most reliable data are the visual observations from aboard the steamer Dora and the record of tephra falls at Kodiak [see figs. 1, 4, in original text] (Martin, 1913; Griggs, 1922). Martin visited Kodiak, Uyak, Katmai village, and Cold Bay [see fig. 1 in original text] in August of 1912 and gathered what accounts he could from residents of the district, but he did not venture inland to the volcanoes nor was he able to interview anyone from the two bands of native hunter-fishermen said to have been within 30 and 40 km, respectively, north and south of Novarupta at the time of the initial outburst. Reconstructions of the eruptive sequence by Griggs (1922) and Fenner (1923, 1925, 1950) are heavily inferential, overinterpretive both of Martin's data and of latter-day interviews with people said to have been at Savonoski when the eruption began (see below), and suffer badly from the incorrect assumption that much of the tephra had come from Mt. Katmai. The following is a critical reappraisal of what appear to be the facts, as assembled largely by G.C. Martin (1913; and unpublished USGS field notes); all times cited are adjusted to Alaskan local time.
"Earthquakes were reported to have been felt at Katmai village (30 km SSE of Novarupta) as early as the evening of 31 May, and severe shocks were felt at Uyak, Kanatak, and Nushugak (200 km WNW) on 4 and 5 June. On the morning of 6 June, explosions were heard at Nushugak and at Seldovia (240 km ENE) but there were no reports of accompanying seismicity or ash clouds. The same morning the Dora left Uyak at 0845 and steamed north-eastward up Shelikof Strait, the Katmai-group volcanoes in full view with a 'strong westerly breeze and fine clear weather,' but no one aboard noticed a tephra column until 1300 (when the vessel was ~88 km southeast of Novarupta). That column was clearly Plinian and, as shown below by the stratigraphic data, it was predominantly rhyolitic; the cloud overtook the Dora by 1500 and began dropping ash at Kodiak (170 km ESE) [see figs. 1, 4, in original text] by 1700.
"Separate interviews with two individuals said to have been in or near Savonoski (30 km N) on the morning of 6 June were conducted in 1918 (Griggs, 1922, p. 17) and in 1923 (Fenner, 1925, p. 216); these have been interpreted to suggest that the ash flow in the VTTS began in the morning several hours prior to the first high tephra column. This is quite unlikely in view of: (1) the record of the Dora; (2) the fact that the basal tephra layer in the VTTS, the distinctively rhyolitic Layer A, does not occur atop the ash-flow deposit; and (3) the common association of pumiceous pyroclastic flows with the collapse of vertical eruption columns. Preliminary eruptive activity at Novarupta on the morning of 6 June is quite reasonable and may be the best explanation of the noise and dust reported that morning at Savonoski and the explosions heard at Nushugak and Seldovia; but a major eruption column and a rhyolitic ash flow several km^3 in volume are certainly excluded prior to 1300.
"Major shocks that punctuated virtually continuous seismic activity were reported locally at ~1300 and ~2300 on 6 June and ~2240 on 7 June. These times are not necessarily very accurate. The first instrumentally recorded teleseism (at Seattle) is reported to have arrived at 1241 on 6 June (Fenner, 1925). Harvard, Ottawa, and several Eurasian stations recorded many teleseisms originating in southwest Alaska between 1805 on 6 June and ~2100 on 11 June. One of these near midnight on 6/7 June has been estimated at magnitude 6.4 and another at 0606 on 10 June at magnitude 7.0 (Coffman and von Hake, 1973). Earthquakes following the main phases of the eruption were felt at Cold Bay (60 km SSW) on 50 of the 70 days through mid-August (Fenner, 1925).
"A great explosion, accompanied by an earthquake felt at Cold Bay ~1300 on 6 June (Martin, 1913), was audible throughout the region and close in time to the first recorded teleseism and to the first sighting of tephra by the Dora. Another blast at ~1500 on 6 June, for which no accompanying earthquake was noted, may have been the most severe outburst of all, being heard for hundreds of kilometers (Martin, 1913). Martin suggested, but did not cite any evidence for, explosions synchronous with the large earthquakes felt nearby at ~2300 on 6 June and 2240 on 7 June. There were, however, reports of loud noises between midnight and 0200 on 8 June, at Katanak (95 km SW) and at Cordova (590 km ENE) (Martin, 1913; Fenner, 1925). Explosions continued to be heard, some as far away as Juneau (1200 km) until 10 June, though how many of the noises may have been thunder is impossible to assess.
"Major tephra eruptions, first noted by the Dora at 1300 on 6 June, continued to fall heavily on downwind settlements nearby until 9 June. The principal sector of dispersal was southeastward [see fig. 1 in original text], and the most distant positive record of ashfall was in Puget Sound (2400 km SE); atmospheric effects were worldwide (Griggs, 1922; Volz, 1975). In the main downwind direction at Kodiak (170 km ESE) there were three discrete periods of ashfall [see fig. 4 in original text]: (1) 1700 6 June until 0910 7 June; (2) ~1200 7 June until 1430 8 June; and (3) during the night of 8/9 June. The 9th of June dawned clear, and no further ash-falls were recorded on Kodiak Island. A major vapor plume and, possibly, sporadic ashfalls close to the source lasted all summer (Martin, 1913; Griggs, 1922; Fenner, 1925). Timing of the emplacement of the Novarupta dome is poorly known; its extrusion followed the last major tephra fall and was complete at the time of discovery on 31 July 1916.
"Details of correlation between audible explosions, tephra falls, and seismic events are not well known. Martin (1913) is the principal source, but his article has been misread and overinterpreted and ensuing errors propagated in successive publications. The seismicity does not correlate very well with eruptive events, and indeed there need be no correspondence (e.g. Filson and others, 1973; Nairn and others, 1976; Yokoyama and others, 1981). Much of the seismic activity seems more likely to have been related to fitful subsidence of Katmai and Novarupta calderas.
"At the onset of eruption, no one is known to have had a view of the VTTS (much less the Novarupta area itself), and only the party of native fishermen then southwest of Katmai village en route to Cold Bay may have been in a position to see Mt. Katmai. The Savonoski interviews (above) smack of ex post facto embellishment, although Martin (1913, p. 147) accepted a third hand report in 1912 that the villagers there may have seen Mt. Katmai after its collapse, but before 9 June. It is not clear where they might have had such a view, because, even notwithstanding the ash clouds, Mt. Katmai is not visible from Savonoski or along their escape route down the lake to Naknek [see fig. 1 in original text]. Martin, Griggs, and Fenner accepted such reports to mean that Mt. Katmai had lost its top by the afternoon of 6 June. This may be true, but it is not clear how Mt. Katmai could have been seen at all during the eruptive interval at Novarupta or what meaning should be attached to such expressions as 'blown off' or 'blown up.' No definitive geologic evidence has been found to fix the timing of Mt. Katmai's collapse, but it may be a reasonable inference that in addition to the syneruptive earthquakes, much of the summer-long seismicity can be attributed to such collapse, as well as to tectonic adjustments over a somewhat wider area, or even to dome emplacement at Novarupta."
Hildreth (1983) also reports that "pumice in the intial fall unit (A) is 100% rhyolite, but fall units atop the ash flow are >98% datcite; black andesitic scoria is common only in the ash flows and in near-vent air-fall tephra." He also states: The Novarupta lava dome is "diameter 380 m, its hieight ~65 m, and the intermediate (mostly dacite) lava interbanded with the rhyolite consitutes no more than 5% of the exposure; most of the conspicuous banding reflects textural variation in the rhyolite."
Fierstein and Hildreth (2001) estimate that the Novarupta eruption of 1912 ejected "at least 17 cubic km of fall deposits and about 11 cubic km of ash-flow tuff (ignimbrite) * * * emplaced in about 60 hours, representing a magma volume of about 13 cubic km (Fierstein and Hildreth, 1992). Hildreth (1987) estimates the volume of the Novarupta lava dome to be 0.005 cubic km.
Impact: The ashfall from the eruption at Novarupta was widespread. From Riehle and others (2000): "Humans directly affected by the eruption were located mainly in four areas: Katmai village, 30 km southeast of Novarupta; a pair of settlements on the Ukak and Savonoski Rivers of which one was sited near the foot of the ashflow deposit, 20 km northwest of the vent; Douglas village, 80 km to the east; and Kodiak village, 180 km east. Most of the Douglas and Katmai village inhabitants were at summer fishing camps on Kaflia Bay. The few Katmai villagers left behind fled in fear early on 6 June as the frequency of premonitory earthquakes increased. They were in bidarkas (kayaks) at Cape Kubugakli when the eruption occurred."
From Adelman, 2002: "Winds pushed the ash cloud east and within a few hours, ash from a huge volcanic eruption began to fall on Kodiak Island, approximately 100 miles (170 km) southeast of the volcano. Within several hours
ash fell on Vancouver, British Columbia and Seattle, Washington. The next day the ash cloud passed over Virginia, and by June 17th it reached the skies above Algeria in Africa (Fierstein and Hildreth, 2001).
"* * * During the next three days, life on Kodiak Island was immobilized during the 60-hour eruption. Darkness and suffocating conditions caused by the falling ash and sulfur dioxide gas rendered villagers helpless [see fig. 3 in original text]. Among Kodiak's 500 inhabitants, sore eyes and respiratory problems were widespread. Water became
undrinkable. Radio communications were disrupted and visibility was nil. Roofs in the village collapsed under the weight of more than a foot of ash. Buildings were destroyed as avalanches of ash rushed down from nearby hillsides (Fierstein and Hildreth, 2001).
"On June 9th Kodiak villagers saw the first clear, ash-free skies in three days, but their environment had changed fundamentally. Wildlife on Kodiak Island and in the Katmai region was decimated by ash and
acid rain from the eruption. Bears and other large animals were blinded by thick ash and many starved to death because large numbers of plants and small animals were smothered in the eruption. Birds blinded and coated by volcanic ash fell to the ground. Even the region's prolific mosquitoes were exterminated. Aquatic organisms in the region perished in the ash-clogged waters. Salmon, in all stages of life, were destroyed by the eruption and its aftereffects. From 1915 to 1919, southwestern Alaska's salmon-fishing industry was
devastated (Fierstein, 1998). The biological impact was far worse overall than that of the Exxon Valdez oil spill in 1989 (Fierstein and Hildreth, 2001).
"The impact to the land did not cease when the eruption ended. A number of moderate sized lahars - volcanic debris flows consisting of rapidly flowing mixtures of water, mud, and rock debris - resulted
from the 1912 eruption. The most publicized lahars occurred a few years after the eruption itself. A landslide, triggered by earthquakes during the 1912 eruption, dammed the Katmai River in Katmai Canyon. The Katmai River remained dammed for three years until a very heavy snowmelt in 1915; the dam was breached and an enormous flood broke out into Katmai Canyon. Prior to his exploration of the Valley of Ten Thousand Smokes, botanist Dr. Robert F. Griggs landed on the shore of Katmai Bay in 1915-nearly 19 miles (30 km) downstream from Katmai Canyon. There he 'found the countryside ravaged by a great flood whose waters were just subsiding.' (Griggs, 1922). Although Griggs called it a 'flood', a great volume of debris was also transported during this event. The tidal-flat area, 6 miles (10 km) wide, was choked with pumice and ash, turning upriver stretches of land into quicksand and destroying Katmai village (already abandoned in 1912). Trees were snapped off near ground level for several miles by the violent impact of the water, a fan of huge boulders was deposited at the mouth of the canyon, and the water volume was so great that it flooded the valley to a depth of approximately 10 feet (3 m) (J. Fierstein, personal communication, 2002)." [5] [6] [7] [8] [10] [60] [11] [52] [15] [66] [18] [67] [20] [21] [23] [68] [3]
Other Impacts: From Riehle and others (2000): "The effects of the tephra on animals and vegetation, of major importance to a subsistence culture, depend critically on thickness of tephra and the particular species. Virtually all animals either died or left areas of heaviest tephra fall on the Alaska Peninsula; Griggs (1922) observed bear and fox tracks on the beach of Katmai Bay in 1915, but the only signs of animal life in the upper reaches of the Katmai River valley were occasional birds. By 1919, however, nesting birds, mice and ground squirrels in the same area had increased notably (Griggs, 1922, pg. 164). Cattle at Kodiak, where 20 cm of tephra fell, survived the eruption but then were removed from the island until pastures had fully revegetated 2 years later (Griggs, 1922, p. 44). In general, mammals in the areas of heaviest tephra on Kodiak Island were not seriously affected except for malnutrition (Evermann, 1914), although smaller mammals may have suffered more heavily than larger ones (Erskine, 1962). Caribou on the Alaska Peninsula abraded their teeth on volcanic ash to the point of starvation after a relatively minor eruption of Aniakchak Crater in 1931; many new-born calves were lost as the herd migrated from the area of ashfall (Trowbridge, 1976). Probably the same occurred in areas of even light tephra on the Alaska Peninsula after the 1912 eruption. Caribou graze on low-standing mosses and vegetation whereas moose browse on shrubs and grasses which are more easily cleared of tephra by wind and rain.
"Effects of tephra on salmon are complicated because different species (mainly coho, sockeye, and pinks in this part of Alaska) have different life cycles and spawning ages, and require different types of spawning beds. Salmon were just beginning to enter streams on the Peninsula and in the Kodiak Islands at the time of the eruption. Those in areas of more than about 10 cm tephra either suffocated in tephra-laden waters or returned to the sea, from which they periodically attempted to re-enter the streams (Evermann, 1914). Streams in areas of lighter tephra generally cleared in time to permit late spawners to enter in 1912, whereas those in areas of heavy tephra on the Peninsula were still unsuitable for spawning because of eroding tephra and unstable beds as much as 5 years after the eruption (Griggs, 1922, pg. 161). * * * [S]ome streams on western Afognak Island were devoid of fish food a year after the eruption (Evermann, 1914).
"The impact of the eruption on the salmon resource was not fully realized, however, until several years after the eruption. Sockeye returns to the Kodiak Islands began to decline in 1915 (pink salmon spawn after 2 years, sockeyes and coho after 3-6 years) and continued to decline until 1920 (Eicher and Rounsefell, 1957). Thus, immediately after the eruption, salmon were still available as a food resource although opportunities to take them from streams in areas of 20 cm tephra or more were probably limited. Additionally, marine shellfish were killed in significant numbers in areas of heavy tephra, and even cod were reported to have left traditional grounds near Kodiak Island (Evermann, 1914, pg. 62).
"The details of vegetative recovery, recorded by botanist Robert Griggs (1922), are as varied as was the impact on salmon. In areas of heavy tephra, tree limbs were broken, grasses and shrubs were buried, and landslides and floods excavated or deeply buried trees growing in floodplains and at the foot of steep slopes. On Kodiak Island, grasses and shrubs had recovered within 2-3 years; recovery was not as much by reseeding as by sending up shoots from existing root systems. Some plants survived as much as 3 years of burial (Griggs, 1922, pg. 51). Some willows survived even deep burial by sending out adventitious roots just below the new ground surface. Experiments confirmed that the tephra had few available nutrients but would support plant growth if properly fertilized." [27] [30] [31] [32] [69] [6] [10] [70] [12] [71] [13] [11] [34] [68] [20] [21] [24] [72] [73] [35] [36] [37] [38]
Images
References Cited
[1] The compositionally zoned eruption of 1912 in the Valley of Ten Thousand Smokes, Katmai National Park, Alaska, 1983
Hildreth, Wes, 1983, The compositionally zoned eruption of 1912 in the Valley of Ten Thousand Smokes, Katmai National Park, Alaska: Journal of Volcanology and Geothermal Research, v. 18, n. 1-4, p. 1-56.[2] Volcanoes of the world [2nd edition], 1994
Simkin, Tom, and Siebert, Lee, 1994, Volcanoes of the world [2nd edition]: Tucson, Arizona, Geoscience Press, 349 p.[3] The great eruption of 1912, 2002
Adleman, Jennifer, 2002, The great eruption of 1912: National Park Service Alaska Park Science Winter 2002, Anchorage, AK, http://www.arlis.org/docs/vol1/52558645/52558645v1no1.pdf , p. 4-11.
full-text PDF 1.6 MB [4] The Katmai eruption [June 1912], 1912
Clark, G. A., 1912, The Katmai eruption [June 1912]: Bulletin of the Seismological Society of America, v. 2, p. 226-229.[5] Report on the eruption of Katmai volcano, 1912
Dailey, I. M., 1912, Report on the eruption of Katmai volcano: Bulletin of the American Geographical Society of New York, v. 44, n. 9, p. 641-644.[6] People and pumice on the Alaska Peninsula, 1979
Dumond, D. E., 1979, People and pumice on the Alaska Peninsula: in Sheets, P. D. and Grayson, D. K., (eds.), Volcanic activity and human ecology, New York, NY, Academic Press, p. 373-390.[7] Katmai, 1962
Erskine, W. F., 1962, Katmai: London, New York, Toronto, Abelard-Schuman, 223 p.[8] The Valley of Ten Thousand Smokes, 1984
Fierstein, Judy, 1984, The Valley of Ten Thousand Smokes: Anchorage, AK, Alaska Natural History Association, 16 p.[9] The plinian eruptions of 1912 at Novarupta, Katmai National Park, Alaska, 1992
Fierstein, Judy, and Hildreth, Wes, 1992, The plinian eruptions of 1912 at Novarupta, Katmai National Park, Alaska: Bulletin of Volcanology, v. 54, n. 8, p. 646-684.[10] Can another great volcanic eruption happen in Alaska?, 1998
Fierstein, Judy, Hildreth, Wes, Hendley, J. W. II., and Stauffer, P. H., 1998, Can another great volcanic eruption happen in Alaska?: U.S. Geological Survey Fact Sheet FS 0075-98, 2 p.
full-text PDF 462 KB [11] The Valley of Ten Thousand Smokes, 1922
Griggs, R. F., 1922, The Valley of Ten Thousand Smokes: Washington, DC, National Geographic Society, 340 p., 3 sheets, scale unknown.[12] The beginnings of revegetation in Katmai Valley, 1919
Griggs, R. F., 1919, The beginnings of revegetation in Katmai Valley: in Scientific Results of the Katmai Expedition of the National Geographic Society Paper, The Ohio Journal of Science, v. 19, p. 318-342.[13] The recovery of vegetation at Kodiak, 1919
Griggs, R. F., 1919, The recovery of vegetation at Kodiak: in Scientific Results of the Katmai Expedition of the National Geographic Society Paper, The Ohio Journal of Science, v. 19, p. 1-57.[14] New perspectives on the eruption on 1912 in the Valley of Ten Thousand Smokes, Katmai National Park, Alaska, 1987
Hildreth, Wes, 1987, New perspectives on the eruption on 1912 in the Valley of Ten Thousand Smokes, Katmai National Park, Alaska: Bulletin of Volcanology, v. 49, n. 5, p. 680-693.[15] Katmai volcanic cluster and the great eruption of 1912, 2000
Hildreth, Wes, and Fierstein, Judy, 2000, Katmai volcanic cluster and the great eruption of 1912: Geological Society of America Bulletin, v. 112, n. 10, p. 1594-1620, 6 sheets, scale unknown.[16] Complex proximal deposition during the Plinian eruptions of 1912 at Novarupta, Alaska, 2004
Houghton, B. F., Wilson, C. J. N., Fierstein, J., and Hildreth, W., 2004, Complex proximal deposition during the Plinian eruptions of 1912 at Novarupta, Alaska: Bulletin of Volcanology, v. 66, n. 2, p. 95-113.[17] Depth of the ash flow deposit in the Valley of Ten Thousand Smokes, Katmai National Park, Alaska, 1991
Kienle, Juergen, 1991, Depth of the ash flow deposit in the Valley of Ten Thousand Smokes, Katmai National Park, Alaska: Geophysical Research Letters, v. 18, n. 8, p. 1533-1536.[18] The recent eruption of Katmai Volcano in Alaska: an account of one of the most tremendous volcanic explosions known in history, 1913
Martin, G. C., 1913, The recent eruption of Katmai Volcano in Alaska: an account of one of the most tremendous volcanic explosions known in history: National Geographic Magazine, v. 24, p. 131-181.[19] The eruption of Katmai, Alaska, 1912, 1930
Okimura, H., 1930, The eruption of Katmai, Alaska, 1912: The Volcano Letter, v. 305, p. 1-3.
full-text PDF 924 KB [20] Tephrochronology of the Brooks River Archaeological District, Katmai National Park and Preserve, Alaska: what can and cannot be done with tephra deposits, 2000
Riehle, J. R., Dumond, D. E., Meyer, C. E., and Schaaf, J. M., 2000, Tephrochronology of the Brooks River Archaeological District, Katmai National Park and Preserve, Alaska: what can and cannot be done with tephra deposits: in McGuire, W. J., Griffiths, D. R., Hancock, P. L., and Stewart, I. S., (eds.), The archaeology of geological catastrophes, Geological Society, London Special Publication 171, p. 245-266.[21] Witness, firsthand accounts of the largest volcanic eruption in the twentieth century, 2004
Schaaf, J. M., 2004, Witness, firsthand accounts of the largest volcanic eruption in the twentieth century: Anchorage, AK, National Park Service, Lake Clark-Katmai Studies Center, unpaged.[22] Some effects of recent volcanic ash falls with special reference to Alaska, 1959
Wilcox, R. E., 1959, Some effects of recent volcanic ash falls with special reference to Alaska: in Investigations of Alaskan volcanoes, U.S. Geological Survey Bulletin 1028-N, p. 409-476, 5 sheets, scale unknown.
full-text PDF 1.5 MB
plate 54 PDF 76 KB
plate 55 PDF 194 KB
plate 56 PDF 234 KB
plate 57 PDF 177 KB
plate 58 PDF 140 KB [23] Taal, Asama-Yama, and Katmai, 1912
McAide, A. G., 1912, Taal, Asama-Yama, and Katmai: Bulletin of the Seismological Society of America, v. 2, no. 4, p. 233-242.[24] Effects of lake fertilization by volcanic activity on abundance of salmon, 1957
Eicher, G. J., and Rounsefell, G. A., 1957, Effects of lake fertilization by volcanic activity on abundance of salmon: Limnology and Oceanography, v. 2, no. 2, p. 70-76.[25] Importance of Novarupta during the eruption of Mt. Katmai, Alaska, in 1912, 1955
Curtis, G. H., 1955, Importance of Novarupta during the eruption of Mt. Katmai, Alaska, in 1912 [abs.]: Geological Society of America Bulletin, v. 66, n. 12 pt 2, p. 1547.[26] Eruption of Mount Matmai, Alaska, and special report, 1914
Perry, K. W., 1914, Eruption of Mount Matmai, Alaska, and special report: in Annual report of the United States Revenue-Cutter Service, Washington, D.C., Government Printing Office, p. 50-51, 115-120.[27] Untitled report on the effect of the eruption of Katmai Volcano on fisheries, animals, and plant life of the Afognak Island Reservation, 1914
Ball, Edward M., 1914, Untitled report on the effect of the eruption of Katmai Volcano on fisheries, animals, and plant life of the Afognak Island Reservation: in Evermann, Barton W. (ed.), Alaska fisheries and fur seal industries, U.S. Bureau of Fisheries Document 797, p. unknown.[28] Geologic map of the Katmai volcanic cluster, Katmai National Park, Alaska, 2003
Hildreth, Wes, and Fierstein, Judy, 2003, Geologic map of the Katmai volcanic cluster, Katmai National Park, Alaska: U.S. Geological Survey Miscellaneous Investigation Series Map I 2778, unpaged, 1 sheet, scale 1:63,360.
full-text PDF 23.9 MB [29] Ejecta dispersal and dynamics of the 1912 eruptions at Novarupta, Katmai National Park, Alaska, 1986
Fierstein, Judy, and Hildreth, Wes, 1986, Ejecta dispersal and dynamics of the 1912 eruptions at Novarupta, Katmai National Park, Alaska [abs.]: Eos, v. 67, n. 44, p. 1246.[30] Do volcanic explosions affect our climate?, 1913
Abbot, C. G., 1913, Do volcanic explosions affect our climate?: National Geographic Magazine, v. 24, p. 181-198.[31] Volcanoes and climate, 1913
Abbot, C. G., and Fowle, F. E., 1913, Volcanoes and climate: Smithsonian Miscellaneous Collections, v. 60, n. 29, 24 p.[32] Volcanic dust veils and climatic variations, 1915
Arctowski, Henryk, 1915, Volcanic dust veils and climatic variations: Annals of the New York Academy of Sciences, v. 26, p. 149-174.[33] The 1912 eruption in the Valley of Ten Thousand Smokes, Katmai National Park: a summary of the stratigraphy and petrology of the ejecta, 1984
Hildreth, Wes, Fierstein, J. E., Grunder, A. L., and Jager, Larry, 1984, The 1912 eruption in the Valley of Ten Thousand Smokes, Katmai National Park: a summary of the stratigraphy and petrology of the ejecta: in Coonrad, W. L. and Elliott, R. L., (eds.), The United States Geological Survey in Alaska: accomplishments during 1981, U.S. Geological Survey Circular C 0868, p. 37-39.[34] The effect upon atmospheric transparency of the eruption of Katmai volcano, 1913
Kimball, H. H., 1913, The effect upon atmospheric transparency of the eruption of Katmai volcano: Monthly Weather Review, v. 41, Washington, DC, American Meteorological Society, p. 153-159.[35] Volcanic eruptions and solar radiation intensities, 1918
Kimball, H.H., 1918, Volcanic eruptions and solar radiation intensities: Monthly Weather Review, v. 46, p. 355-356.[36] The effect of the atmospheric turbidity of 1912 on solar radiation intensities and skylight polarization, 1913
Kimball, H.H., 1913, The effect of the atmospheric turbidity of 1912 on solar radiation intensities and skylight polarization: Bulletin Mt. Weather Observatory, v. 5, p. 295-312.[37] The dense haze of June 10-11, 1912, 1912
Kimball, H.H., 1912, The dense haze of June 10-11, 1912: Bulletin Mt. Weather Observatory, v. 5, p. 161-165.[38] Volcanic dust and other factors in the production of climactic changes and their possible relation to ice ages, 1913
Humphreys, W.J., 1913, Volcanic dust and other factors in the production of climactic changes and their possible relation to ice ages: Bulletin Mt. Weather Observatory, v. 6, p. 1-34.[39] The stratigraphy of the ejecta from the 1912 eruption of Mount Katmai and Novarupta, Alaska, 1968
Curtis, G. H., 1968, The stratigraphy of the ejecta from the 1912 eruption of Mount Katmai and Novarupta, Alaska: in Coats, R. R., Hay, R. L., and Anderson, C. A., (eds.), Studies in volcanology, Geological Society of America Memoir MWR 0116, p. 153-210.[40] Preliminary volcano-hazard assessment for the Katmai volcanic cluster, Alaska, 2001
Fierstein, Judy, and Hildreth, Wes, 2001, Preliminary volcano-hazard assessment for the Katmai volcanic cluster, Alaska: U.S. Geological Survey Open-File Report 00-0489, 50 p., 1 plate, scale not applicable.
full-text PDF 28.8 MB [41] The vent of the 1912 Katmai eruption: gravity and magnetic measurements, 1991
Goodliffe, A. M., Stone, D. B., Kienle, Juergen, and Kasameyer, Paul, 1991, The vent of the 1912 Katmai eruption: gravity and magnetic measurements: Geophysical Research Letters, v. 18, n. 8, p. 1521-1524.[42] Magma storage prior to the 1912 eruption at Novarupta, Alaska, 2002
Hammer, J. E., Rutherford, M. J., and Hildreth, Wes, 2002, Magma storage prior to the 1912 eruption at Novarupta, Alaska: Contributions to Mineralogy and Petrology, v. 144, n. 2, p. 144-162.[43] The 1912 eruption in the Valley of Ten Thousand Smokes, Katmai National Monument, Alaska, 1981
Hildreth, W., 1981, The 1912 eruption in the Valley of Ten Thousand Smokes, Katmai National Monument, Alaska [abs.]: in IAVCEI International Association of Volcanology and Chemistry of the Earth's Interior, Symposium on Arc Volcanism, Tokyo & Hakone, Japan, August 28-September 9, 1981, p. 126-127.[44] The timing of caldera collapse at Mount Katmai in response to magma withdrawal toward Novarupta, 1991
Hildreth, Wes, 1991, The timing of caldera collapse at Mount Katmai in response to magma withdrawal toward Novarupta: Geophysical Research Letters, v. 18, n. 8, p. 1541-1544.[45] The Katmai eruption of 1912: was the magma stored beneath Novarupta, Trident, or Mount Katmai? Petrochemical and temporal evidence, 1990
Hildreth, Wes, 1990, The Katmai eruption of 1912: was the magma stored beneath Novarupta, Trident, or Mount Katmai? Petrochemical and temporal evidence [abs.]: Eos, v. 71, n. 43, p. 1691.[46] Two-dimensional kinematic and rheological modeling of the 1912 pyroclastic flow, Katmai, Alaska, 1988
Beget, J. E., and Limke, A. J., 1988, Two-dimensional kinematic and rheological modeling of the 1912 pyroclastic flow, Katmai, Alaska: Bulletin of Volcanology, v. 50, n. 3, p. 148-160.[47] On the hot "lahar" (mud flow) of the Valley of Ten Thousand Smokes, Alaska, 1922
Escher, B. G., 1922, On the hot "lahar" (mud flow) of the Valley of Ten Thousand Smokes, Alaska: in Koninklijke Akademie van Wetenschappen, 24, Proceedings, Science Section, p. 282-293.[48] The origin and mode of emplacement of the great tuff deposit of the Valley of Ten Thousand Smokes, 1923
Fenner, C. N., 1923, The origin and mode of emplacement of the great tuff deposit of the Valley of Ten Thousand Smokes: National Geographic Society Contributed Technical Papers, Katmai Series 0001, 74 p.[49] Tuffs and other volcanic deposits of Katmai and Yellowstone Park, 1937
Fenner, C. N., 1937, Tuffs and other volcanic deposits of Katmai and Yellowstone Park: Transactions of the American Geophysical Union, part 1, v. 18, p. 236-239.[50] The great hot mud flow of the Valley of Ten Thousand Smokes (Katmai, Alaska), 1919
Griggs, R. F., 1919, The great hot mud flow of the Valley of Ten Thousand Smokes (Katmai, Alaska): in Scientific Results of the Katmai Expedition of the National Geographic Society Paper III, The Ohio Journal of Science, v. 19, p. 117-142.[51] Observations on the incandescent sand flow of the Valley of Ten Thousand Smokes, 1923
Griggs, R. F., 1923, Observations on the incandescent sand flow of the Valley of Ten Thousand Smokes: Koninklijke Akademie van Wetenschappen, Amsterdam, Proceedings Ser. Science, v. 25, p. 42-50.[52] Geomorphic role of snow and ice during the Katmai 1912 eruption, 1973
Hamilton, T. D., 1973, Geomorphic role of snow and ice during the Katmai 1912 eruption [abs.]: Abstracts with Programs - Geological Society of America, v. 5, n. 1, p. 48-49.[53] Historical unrest at large calderas of the world, 1988
Newhall, C.G., and Dzurisin, Daniel, 1988, Historical unrest at large calderas of the world: U.S. Geological Survey Bulletin 1855, v. 1-2, 1108 p.[54] A chemical study of the fumaroles of the Katmai region, 1923
Allen, E. T., and Zies, E. G., 1923, A chemical study of the fumaroles of the Katmai region: National Geographic Society Contributed Technical Papers, Katmai Series 0002, p. 75-155.[55] The floor of the Valley of Ten Thousand Smokes, 1923
Cole, G. A. James., 1923, The floor of the Valley of Ten Thousand Smokes: Nature, v. 112, p. 251.[56] The Valley of Ten Thousand Smokes: National Geographic Society explorations in the Katmai district of Alaska, 1917
Griggs, R. F., 1917, The Valley of Ten Thousand Smokes: National Geographic Society explorations in the Katmai district of Alaska: National Geographic Magazine, v. 31, n. 1, p. 13-68.[57] The Valley of Ten Thousand Smokes: an account of the discovery and exploration of the most wonderful volcanic region in the world, 1918
Griggs, R. F., 1918, The Valley of Ten Thousand Smokes: an account of the discovery and exploration of the most wonderful volcanic region in the world: National Geographic Magazine, v. 33, n. 2, p. 115-169.[58] Are the Ten Thousand Smokes real volcanoes?, 1919
Griggs, R. F., 1919, Are the Ten Thousand Smokes real volcanoes?: in Scientific Results of the Katmai Expedition of the National Geographic Society Paper, The Ohio Journal of Science, v. 19, p. 97-116.[59] The Katmai National Monument and the Valley of Ten Thousand Smokes, 1919
Griggs, R. F., 1919, The Katmai National Monument and the Valley of Ten Thousand Smokes: Science, v. 49, n. 1262, p. 236-237.[60] Our greatest national monument: The National Geographic Society completes its explorations in the Valley of Ten Thousand Smokes, 1921
Griggs, R. F., 1921, Our greatest national monument: The National Geographic Society completes its explorations in the Valley of Ten Thousand Smokes: National Geographic Magazine, v. 40, n. 3, p. 219-292.[61] The gas vents of the Katmai eruption, 1926
Jaggar, T. A., 1926, The gas vents of the Katmai eruption: The Volcano Letter, v. 62, p. 1.
full-text PDF 329 KB [62] The water soluble salt content, the ferrous iron content and the acidity of Katmai volcanic ash, 1919
Shipley, J. W., 1919, The water soluble salt content, the ferrous iron content and the acidity of Katmai volcanic ash: in Scientific Results of the Katmai Expedition of the National Geographic Society, The Ohio Journal of Science, v. 19, p. 224-229.[63] Valley of Ten Thousand Smokes, 1919
Shipley, J. W., 1919, Valley of Ten Thousand Smokes: Science, v. 49, n. 1277, p. 489-491.[64] Seismicity of the caldera-making eruption of Mount Katmai, Alaska in 1912, 1992
Abe, Katsuyuki, 1992, Seismicity of the caldera-making eruption of Mount Katmai, Alaska in 1912: Bulletin of the Seismological Society of America, v. 82, n. 1, p. 175-191.[65] The Katmai region, Alaska, and the great eruption of 1912, 1920
Fenner, C. N., 1920, The Katmai region, Alaska, and the great eruption of 1912: Journal of Geology, v. 28, n. 7, p. 569-606.[66] First into Katmai, 1947
Horner, M. A., and Brain, Gladys, 1947, First into Katmai: Alaska Life, v. 10, n. 1, p. 6-7, 24-26.[67] Alaska Peninsula-Aleutian Islands, 1958
Powers, H. A., 1958, Alaska Peninsula-Aleutian Islands: in Williams, H., (ed.), Landscapes of Alaska, Los Angeles, CA, University of California Press, p. 61-75.[68] Angry Earth, 1946
Lowney, P. B., 1946, Angry Earth: Alaska Life: the Territorial Magazine, v. 9, n. 4, p. 2.[69] Effect upon atmospheric transparency of the Alaskan eruption, 1913
Clark, J. E., 1913, Effect upon atmospheric transparency of the Alaskan eruption: Royal Meteorological Society, Quarterly Journal, v. 39, p. 219-220.[70] The effect of the eruption of Katmai on land vegetation, 1915
Griggs, R. F., 1915, The effect of the eruption of Katmai on land vegetation: Bulletin of the American Geographical Society of New York, v. 47, p. 193-203.[71] The character of the eruption as indicated by its effect on nearby vegetation, 1919
Griggs, R. F., 1919, The character of the eruption as indicated by its effect on nearby vegetation: in Scientific Results of the Katmai Expedition of the National Geographic Society Paper, The Ohio Journal of Science, v. 19, n. 3, p. 173-209.[72] Distribution of turbidity after the 1912 Katmai eruption in Alaska, 1975
Volz, F. E., 1975, Distribution of turbidity after the 1912 Katmai eruption in Alaska: Journal of Geophysical Research, v. 80, p. 2643-2648.[73] Statistical review of the Alaska salmon fisheries, part II: Chignik to Resurrection Bay, 1931
Rich, Willis H., and Ball, Edward M., 1931, Statistical review of the Alaska salmon fisheries, part II: Chignik to Resurrection Bay: U.S. Bureau of Fisheries Bulletin 46, p. 643-712.Complete Eruption References
Volcanoes of the world [2nd edition], 1994
Simkin, Tom, and Siebert, Lee, 1994, Volcanoes of the world [2nd edition]: Tucson, Arizona, Geoscience Press, 349 p.
Hard Copy held by AVO at FBKS - CEC shelf
Do volcanic explosions affect our climate?, 1913
Abbot, C. G., 1913, Do volcanic explosions affect our climate?: National Geographic Magazine, v. 24, p. 181-198.
Hard Copy held by AVO at FBKS - CEC file cabinet
Volcanoes and climate, 1913
Abbot, C. G., and Fowle, F. E., 1913, Volcanoes and climate: Smithsonian Miscellaneous Collections, v. 60, n. 29, 24 p.
Seismicity of the caldera-making eruption of Mount Katmai, Alaska in 1912, 1992
Abe, Katsuyuki, 1992, Seismicity of the caldera-making eruption of Mount Katmai, Alaska in 1912: Bulletin of the Seismological Society of America, v. 82, n. 1, p. 175-191.
Hard Copy held by AVO at FBKS - CEC file cabinet
The great eruption of 1912, 2002
Adleman, Jennifer, 2002, The great eruption of 1912: National Park Service Alaska Park Science Winter 2002, Anchorage, AK, http://www.arlis.org/docs/vol1/52558645/52558645v1no1.pdf , p. 4-11.
full-text PDF 1.6 MB 
A chemical study of the fumaroles of the Katmai region, 1923
Allen, E. T., and Zies, E. G., 1923, A chemical study of the fumaroles of the Katmai region: National Geographic Society Contributed Technical Papers, Katmai Series 0002, p. 75-155.
Volcanic dust veils and climatic variations, 1915
Arctowski, Henryk, 1915, Volcanic dust veils and climatic variations: Annals of the New York Academy of Sciences, v. 26, p. 149-174.
Two-dimensional kinematic and rheological modeling of the 1912 pyroclastic flow, Katmai, Alaska, 1988
Beget, J. E., and Limke, A. J., 1988, Two-dimensional kinematic and rheological modeling of the 1912 pyroclastic flow, Katmai, Alaska: Bulletin of Volcanology, v. 50, n. 3, p. 148-160.
Hard Copy held by AVO at FBKS - CEC file cabinet
The Katmai eruption [June 1912], 1912
Clark, G. A., 1912, The Katmai eruption [June 1912]: Bulletin of the Seismological Society of America, v. 2, p. 226-229.
Effect upon atmospheric transparency of the Alaskan eruption, 1913
Clark, J. E., 1913, Effect upon atmospheric transparency of the Alaskan eruption: Royal Meteorological Society, Quarterly Journal, v. 39, p. 219-220.
The floor of the Valley of Ten Thousand Smokes, 1923
Cole, G. A. James., 1923, The floor of the Valley of Ten Thousand Smokes: Nature, v. 112, p. 251.
The stratigraphy of the ejecta from the 1912 eruption of Mount Katmai and Novarupta, Alaska, 1968
Curtis, G. H., 1968, The stratigraphy of the ejecta from the 1912 eruption of Mount Katmai and Novarupta, Alaska: in Coats, R. R., Hay, R. L., and Anderson, C. A., (eds.), Studies in volcanology, Geological Society of America Memoir MWR 0116, p. 153-210.
Report on the eruption of Katmai volcano, 1912
Dailey, I. M., 1912, Report on the eruption of Katmai volcano: Bulletin of the American Geographical Society of New York, v. 44, n. 9, p. 641-644.
Hard Copy held by AVO at FBKS - CEC file cabinet
Reminiscences of Alaskan volcanoes, 1918
Dall, W. H., 1918, Reminiscences of Alaskan volcanoes: Scientific Monthly, v. 7, n. 1, p. 80-90.
People and pumice on the Alaska Peninsula, 1979
Dumond, D. E., 1979, People and pumice on the Alaska Peninsula: in Sheets, P. D. and Grayson, D. K., (eds.), Volcanic activity and human ecology, New York, NY, Academic Press, p. 373-390.
Hard Copy held by AVO at FBKS - CEC file cabinet
Katmai, 1962
Erskine, W. F., 1962, Katmai: London, New York, Toronto, Abelard-Schuman, 223 p.
Hard Copy held by AVO at FBKS - CEC file cabinet
On the hot "lahar" (mud flow) of the Valley of Ten Thousand Smokes, Alaska, 1922
Escher, B. G., 1922, On the hot "lahar" (mud flow) of the Valley of Ten Thousand Smokes, Alaska: in Koninklijke Akademie van Wetenschappen, 24, Proceedings, Science Section, p. 282-293.
The Katmai region, Alaska, and the great eruption of 1912, 1920
Fenner, C. N., 1920, The Katmai region, Alaska, and the great eruption of 1912: Journal of Geology, v. 28, n. 7, p. 569-606.
The origin and mode of emplacement of the great tuff deposit of the Valley of Ten Thousand Smokes, 1923
Fenner, C. N., 1923, The origin and mode of emplacement of the great tuff deposit of the Valley of Ten Thousand Smokes: National Geographic Society Contributed Technical Papers, Katmai Series 0001, 74 p.
Earth movements accompanying the Katmai eruption, 1925
Fenner, C. N., 1925, Earth movements accompanying the Katmai eruption: Journal of Geology, v. 33, p. 116-139, 193-223.
Tuffs and other volcanic deposits of Katmai and Yellowstone Park, 1937
Fenner, C. N., 1937, Tuffs and other volcanic deposits of Katmai and Yellowstone Park: Transactions of the American Geophysical Union, part 1, v. 18, p. 236-239.
Hard Copy held by AVO at FBKS - CEC file cabinet
The chemical kinetics of the Katmai eruption, part I-II, 1950
Fenner, C. N., 1950, The chemical kinetics of the Katmai eruption, part I-II: American Journal of Science, v. 248, n. 9, p. 593-627, 697-725, 4 plates, scale unknown.
The Valley of Ten Thousand Smokes, 1984
Fierstein, Judy, 1984, The Valley of Ten Thousand Smokes: Anchorage, AK, Alaska Natural History Association, 16 p.
The plinian eruptions of 1912 at Novarupta, Katmai National Park, Alaska, 1992
Fierstein, Judy, and Hildreth, Wes, 1992, The plinian eruptions of 1912 at Novarupta, Katmai National Park, Alaska: Bulletin of Volcanology, v. 54, n. 8, p. 646-684.
Preliminary volcano-hazard assessment for the Katmai volcanic cluster, Alaska, 2001
Fierstein, Judy, and Hildreth, Wes, 2001, Preliminary volcano-hazard assessment for the Katmai volcanic cluster, Alaska: U.S. Geological Survey Open-File Report 00-0489, 50 p., 1 plate, scale not applicable.
full-text PDF 28.8 MB 
Can another great volcanic eruption happen in Alaska?, 1998
Fierstein, Judy, Hildreth, Wes, Hendley, J. W. II., and Stauffer, P. H., 1998, Can another great volcanic eruption happen in Alaska?: U.S. Geological Survey Fact Sheet FS 0075-98, 2 p.
full-text PDF 462 KB 
The vent of the 1912 Katmai eruption: gravity and magnetic measurements, 1991
Goodliffe, A. M., Stone, D. B., Kienle, Juergen, and Kasameyer, Paul, 1991, The vent of the 1912 Katmai eruption: gravity and magnetic measurements: Geophysical Research Letters, v. 18, n. 8, p. 1521-1524.
Hard Copy held by AVO at FBKS - CEC file cabinet
Hard Copy held by AVO at FBKS - CEC shelf
The effect of the eruption of Katmai on land vegetation, 1915
Griggs, R. F., 1915, The effect of the eruption of Katmai on land vegetation: Bulletin of the American Geographical Society of New York, v. 47, p. 193-203.
Hard Copy held by AVO at FBKS - CEC file cabinet
The Valley of Ten Thousand Smokes: National Geographic Society explorations in the Katmai district of Alaska, 1917
Griggs, R. F., 1917, The Valley of Ten Thousand Smokes: National Geographic Society explorations in the Katmai district of Alaska: National Geographic Magazine, v. 31, n. 1, p. 13-68.
The Valley of Ten Thousand Smokes: an account of the discovery and exploration of the most wonderful volcanic region in the world, 1918
Griggs, R. F., 1918, The Valley of Ten Thousand Smokes: an account of the discovery and exploration of the most wonderful volcanic region in the world: National Geographic Magazine, v. 33, n. 2, p. 115-169.
Are the Ten Thousand Smokes real volcanoes?, 1919
Griggs, R. F., 1919, Are the Ten Thousand Smokes real volcanoes?: in Scientific Results of the Katmai Expedition of the National Geographic Society Paper, The Ohio Journal of Science, v. 19, p. 97-116.
The beginnings of revegetation in Katmai Valley, 1919
Griggs, R. F., 1919, The beginnings of revegetation in Katmai Valley: in Scientific Results of the Katmai Expedition of the National Geographic Society Paper, The Ohio Journal of Science, v. 19, p. 318-342.
The character of the eruption as indicated by its effect on nearby vegetation, 1919
Griggs, R. F., 1919, The character of the eruption as indicated by its effect on nearby vegetation: in Scientific Results of the Katmai Expedition of the National Geographic Society Paper, The Ohio Journal of Science, v. 19, n. 3, p. 173-209.
Hard Copy held by AVO at FBKS - CEC file cabinet
The great hot mud flow of the Valley of Ten Thousand Smokes (Katmai, Alaska), 1919
Griggs, R. F., 1919, The great hot mud flow of the Valley of Ten Thousand Smokes (Katmai, Alaska): in Scientific Results of the Katmai Expedition of the National Geographic Society Paper III, The Ohio Journal of Science, v. 19, p. 117-142.
The Katmai National Monument and the Valley of Ten Thousand Smokes, 1919
Griggs, R. F., 1919, The Katmai National Monument and the Valley of Ten Thousand Smokes: Science, v. 49, n. 1262, p. 236-237.
Hard Copy held by AVO at FBKS - CEC file cabinet
The recovery of vegetation at Kodiak, 1919
Griggs, R. F., 1919, The recovery of vegetation at Kodiak: in Scientific Results of the Katmai Expedition of the National Geographic Society Paper, The Ohio Journal of Science, v. 19, p. 1-57.
Hard Copy held by AVO at FBKS - CEC file cabinet
Our greatest national monument: The National Geographic Society completes its explorations in the Valley of Ten Thousand Smokes, 1921
Griggs, R. F., 1921, Our greatest national monument: The National Geographic Society completes its explorations in the Valley of Ten Thousand Smokes: National Geographic Magazine, v. 40, n. 3, p. 219-292.
The Valley of Ten Thousand Smokes, 1922
Griggs, R. F., 1922, The Valley of Ten Thousand Smokes: Washington, DC, National Geographic Society, 340 p., 3 sheets, scale unknown.
Observations on the incandescent sand flow of the Valley of Ten Thousand Smokes, 1923
Griggs, R. F., 1923, Observations on the incandescent sand flow of the Valley of Ten Thousand Smokes: Koninklijke Akademie van Wetenschappen, Amsterdam, Proceedings Ser. Science, v. 25, p. 42-50.
Geomorphic role of snow and ice during the Katmai 1912 eruption, 1973
Hamilton, T. D., 1973, Geomorphic role of snow and ice during the Katmai 1912 eruption [abs.]: Abstracts with Programs - Geological Society of America, v. 5, n. 1, p. 48-49.
Hard Copy held by AVO at FBKS - CEC file cabinet
Magma storage prior to the 1912 eruption at Novarupta, Alaska, 2002
Hammer, J. E., Rutherford, M. J., and Hildreth, Wes, 2002, Magma storage prior to the 1912 eruption at Novarupta, Alaska: Contributions to Mineralogy and Petrology, v. 144, n. 2, p. 144-162.
The 1912 eruption in the Valley of Ten Thousand Smokes, Katmai National Monument, Alaska, 1981
Hildreth, W., 1981, The 1912 eruption in the Valley of Ten Thousand Smokes, Katmai National Monument, Alaska [abs.]: in IAVCEI International Association of Volcanology and Chemistry of the Earth's Interior, Symposium on Arc Volcanism, Tokyo & Hakone, Japan, August 28-September 9, 1981, p. 126-127.
Hard Copy held by AVO at FBKS - CEC file cabinet
Hard Copy held by AVO at FBKS - CEC shelf
The compositionally zoned eruption of 1912 in the Valley of Ten Thousand Smokes, Katmai National Park, Alaska, 1983
Hildreth, Wes, 1983, The compositionally zoned eruption of 1912 in the Valley of Ten Thousand Smokes, Katmai National Park, Alaska: Journal of Volcanology and Geothermal Research, v. 18, n. 1-4, p. 1-56.
New perspectives on the eruption on 1912 in the Valley of Ten Thousand Smokes, Katmai National Park, Alaska, 1987
Hildreth, Wes, 1987, New perspectives on the eruption on 1912 in the Valley of Ten Thousand Smokes, Katmai National Park, Alaska: Bulletin of Volcanology, v. 49, n. 5, p. 680-693.
The timing of caldera collapse at Mount Katmai in response to magma withdrawal toward Novarupta, 1991
Hildreth, Wes, 1991, The timing of caldera collapse at Mount Katmai in response to magma withdrawal toward Novarupta: Geophysical Research Letters, v. 18, n. 8, p. 1541-1544.
Hard Copy held by AVO at FBKS - CEC file cabinet
Hard Copy held by AVO at FBKS - CEC shelf
Geologic map of the Katmai volcanic cluster, Katmai National Park, Alaska, 2003
Hildreth, Wes, and Fierstein, Judy, 2003, Geologic map of the Katmai volcanic cluster, Katmai National Park, Alaska: U.S. Geological Survey Miscellaneous Investigation Series Map I 2778, unpaged, 1 sheet, scale 1:63,360.
full-text PDF 23.9 MB 
Katmai volcanic cluster and the great eruption of 1912, 2000
Hildreth, Wes, and Fierstein, Judy, 2000, Katmai volcanic cluster and the great eruption of 1912: Geological Society of America Bulletin, v. 112, n. 10, p. 1594-1620, 6 sheets, scale unknown.
The 1912 eruption in the Valley of Ten Thousand Smokes, Katmai National Park: a summary of the stratigraphy and petrology of the ejecta, 1984
Hildreth, Wes, Fierstein, J. E., Grunder, A. L., and Jager, Larry, 1984, The 1912 eruption in the Valley of Ten Thousand Smokes, Katmai National Park: a summary of the stratigraphy and petrology of the ejecta: in Coonrad, W. L. and Elliott, R. L., (eds.), The United States Geological Survey in Alaska: accomplishments during 1981, U.S. Geological Survey Circular C 0868, p. 37-39.
First into Katmai, 1947
Horner, M. A., and Brain, Gladys, 1947, First into Katmai: Alaska Life, v. 10, n. 1, p. 6-7, 24-26.
Complex proximal deposition during the Plinian eruptions of 1912 at Novarupta, Alaska, 2004
Houghton, B. F., Wilson, C. J. N., Fierstein, J., and Hildreth, W., 2004, Complex proximal deposition during the Plinian eruptions of 1912 at Novarupta, Alaska: Bulletin of Volcanology, v. 66, n. 2, p. 95-113.
The gas vents of the Katmai eruption, 1926
Jaggar, T. A., 1926, The gas vents of the Katmai eruption: The Volcano Letter, v. 62, p. 1.
full-text PDF 329 KB 
Depth of the ash flow deposit in the Valley of Ten Thousand Smokes, Katmai National Park, Alaska, 1991
Kienle, Juergen, 1991, Depth of the ash flow deposit in the Valley of Ten Thousand Smokes, Katmai National Park, Alaska: Geophysical Research Letters, v. 18, n. 8, p. 1533-1536.
Hard Copy held by AVO at FBKS - CEC file cabinet
Hard Copy held by AVO at FBKS - CEC shelf
The effect upon atmospheric transparency of the eruption of Katmai volcano, 1913
Kimball, H. H., 1913, The effect upon atmospheric transparency of the eruption of Katmai volcano: Monthly Weather Review, v. 41, Washington, DC, American Meteorological Society, p. 153-159.
Hard Copy held by AVO at FBKS - CEC file cabinet
Angry Earth, 1946
Lowney, P. B., 1946, Angry Earth: Alaska Life: the Territorial Magazine, v. 9, n. 4, p. 2.
Hard Copy held by AVO at FBKS - CEC file cabinet
The recent eruption of Katmai Volcano in Alaska: an account of one of the most tremendous volcanic explosions known in history, 1913
Martin, G. C., 1913, The recent eruption of Katmai Volcano in Alaska: an account of one of the most tremendous volcanic explosions known in history: National Geographic Magazine, v. 24, p. 131-181.
Historical unrest at large calderas of the world, 1988
Newhall, C.G., and Dzurisin, Daniel, 1988, Historical unrest at large calderas of the world: U.S. Geological Survey Bulletin 1855, v. 1-2, 1108 p.
Hard Copy held by AVO at FBKS - CEC shelf
The eruption of Katmai, Alaska, 1912, 1930
Okimura, H., 1930, The eruption of Katmai, Alaska, 1912: The Volcano Letter, v. 305, p. 1-3.
full-text PDF 924 KB 
Alaska Peninsula-Aleutian Islands, 1958
Powers, H. A., 1958, Alaska Peninsula-Aleutian Islands: in Williams, H., (ed.), Landscapes of Alaska, Los Angeles, CA, University of California Press, p. 61-75.
Tephrochronology of the Brooks River Archaeological District, Katmai National Park and Preserve, Alaska: what can and cannot be done with tephra deposits, 2000
Riehle, J. R., Dumond, D. E., Meyer, C. E., and Schaaf, J. M., 2000, Tephrochronology of the Brooks River Archaeological District, Katmai National Park and Preserve, Alaska: what can and cannot be done with tephra deposits: in McGuire, W. J., Griffiths, D. R., Hancock, P. L., and Stewart, I. S., (eds.), The archaeology of geological catastrophes, Geological Society, London Special Publication 171, p. 245-266.
Witness, firsthand accounts of the largest volcanic eruption in the twentieth century, 2004
Schaaf, J. M., 2004, Witness, firsthand accounts of the largest volcanic eruption in the twentieth century: Anchorage, AK, National Park Service, Lake Clark-Katmai Studies Center, unpaged.
The water soluble salt content, the ferrous iron content and the acidity of Katmai volcanic ash, 1919
Shipley, J. W., 1919, The water soluble salt content, the ferrous iron content and the acidity of Katmai volcanic ash: in Scientific Results of the Katmai Expedition of the National Geographic Society, The Ohio Journal of Science, v. 19, p. 224-229.
Valley of Ten Thousand Smokes, 1919
Shipley, J. W., 1919, Valley of Ten Thousand Smokes: Science, v. 49, n. 1277, p. 489-491.
Volcanoes of the world: an illustrated catalog of Holocene volcanoes and their eruptions, 2003
Siebert, L., and Simkin, T., 2002-, Volcanoes of the world: an illustrated catalog of Holocene volcanoes and their eruptions: Smithsonian Institution, Global Volcanism Program Digital Information Series GVP-3, http://volcano.si.edu/search_volcano.cfm, unpaged internet resource.
Volcanoes of Alaska, 1912
Unknown, 1912, Volcanoes of Alaska: National Geographic Magazine, v. 23, p. 824-832.
90-year-old Katmai ash dusts Kodiak, 2004
Unknown, 2004, 90-year-old Katmai ash dusts Kodiak: Alaska, v. 70, n. 1, p. 15.
Some effects of recent volcanic ash falls with special reference to Alaska, 1959
Wilcox, R. E., 1959, Some effects of recent volcanic ash falls with special reference to Alaska: in Investigations of Alaskan volcanoes, U.S. Geological Survey Bulletin 1028-N, p. 409-476, 5 sheets, scale unknown.
full-text PDF 1.5 MB
plate 54 PDF 76 KB
plate 55 PDF 194 KB
plate 56 PDF 234 KB
plate 57 PDF 177 KB
plate 58 PDF 140 KB 
Taal, Asama-Yama, and Katmai, 1912
McAide, A. G., 1912, Taal, Asama-Yama, and Katmai: Bulletin of the Seismological Society of America, v. 2, no. 4, p. 233-242.
Hard Copy held by AVO at FBKS - CEC file cabinet
Effects of lake fertilization by volcanic activity on abundance of salmon, 1957
Eicher, G. J., and Rounsefell, G. A., 1957, Effects of lake fertilization by volcanic activity on abundance of salmon: Limnology and Oceanography, v. 2, no. 2, p. 70-76.
Importance of Novarupta during the eruption of Mt. Katmai, Alaska, in 1912, 1955
Curtis, G. H., 1955, Importance of Novarupta during the eruption of Mt. Katmai, Alaska, in 1912 [abs.]: Geological Society of America Bulletin, v. 66, n. 12 pt 2, p. 1547.
Eruption of Mount Matmai, Alaska, and special report, 1914
Perry, K. W., 1914, Eruption of Mount Matmai, Alaska, and special report: in Annual report of the United States Revenue-Cutter Service, Washington, D.C., Government Printing Office, p. 50-51, 115-120.
Hard Copy held by AVO at FBKS - CEC file cabinet
Untitled report on the effect of the eruption of Katmai Volcano on fisheries, animals, and plant life of the Afognak Island Reservation, 1914
Ball, Edward M., 1914, Untitled report on the effect of the eruption of Katmai Volcano on fisheries, animals, and plant life of the Afognak Island Reservation: in Evermann, Barton W. (ed.), Alaska fisheries and fur seal industries, U.S. Bureau of Fisheries Document 797, p. unknown.
Earthquake history of the United States, 1973
Coffman, J. L., and von Hake, C. A., 1973, Earthquake history of the United States: U.S. Dept. of Commerce, National Oceanic and Atmospheric Administration Publication 41-1, 208 p.
Distribution of turbidity after the 1912 Katmai eruption in Alaska, 1975
Volz, F. E., 1975, Distribution of turbidity after the 1912 Katmai eruption in Alaska: Journal of Geophysical Research, v. 80, p. 2643-2648.
The Katmai eruption of 1912: was the magma stored beneath Novarupta, Trident, or Mount Katmai? Petrochemical and temporal evidence, 1990
Hildreth, Wes, 1990, The Katmai eruption of 1912: was the magma stored beneath Novarupta, Trident, or Mount Katmai? Petrochemical and temporal evidence [abs.]: Eos, v. 71, n. 43, p. 1691.
Statistical review of the Alaska salmon fisheries, part II: Chignik to Resurrection Bay, 1931
Rich, Willis H., and Ball, Edward M., 1931, Statistical review of the Alaska salmon fisheries, part II: Chignik to Resurrection Bay: U.S. Bureau of Fisheries Bulletin 46, p. 643-712.
Volcanic eruptions and solar radiation intensities, 1918
Kimball, H.H., 1918, Volcanic eruptions and solar radiation intensities: Monthly Weather Review, v. 46, p. 355-356.
The effect of the atmospheric turbidity of 1912 on solar radiation intensities and skylight polarization, 1913
Kimball, H.H., 1913, The effect of the atmospheric turbidity of 1912 on solar radiation intensities and skylight polarization: Bulletin Mt. Weather Observatory, v. 5, p. 295-312.
The dense haze of June 10-11, 1912, 1912
Kimball, H.H., 1912, The dense haze of June 10-11, 1912: Bulletin Mt. Weather Observatory, v. 5, p. 161-165.
Volcanic dust and other factors in the production of climactic changes and their possible relation to ice ages, 1913
Humphreys, W.J., 1913, Volcanic dust and other factors in the production of climactic changes and their possible relation to ice ages: Bulletin Mt. Weather Observatory, v. 6, p. 1-34.
Ejecta dispersal and dynamics of the 1912 eruptions at Novarupta, Katmai National Park, Alaska, 1986
Fierstein, Judy, and Hildreth, Wes, 1986, Ejecta dispersal and dynamics of the 1912 eruptions at Novarupta, Katmai National Park, Alaska [abs.]: Eos, v. 67, n. 44, p. 1246.
Seismicity of a caldera collapse; Galapagos Islands 1968, 1973
Filson, John, Simkin, Tom, and Leu, Lei-kuang, 1973, Seismicity of a caldera collapse; Galapagos Islands 1968: Journal of Geophysical Research, v. 78, n. 35, p. 8591-8622.
Pyroclastic eruptions of Ngauruhoe volcano, central North Island, New Zealand, 1976
Nairn, I.A., Hewson, C.A.Y., Latter, J.H., and Wood, C.P., 1976, Pyroclastic eruptions of Ngauruhoe volcano, central North Island, New Zealand: in R.W. Johnson (ed.), Volcanism in Australasia, Elsevier, Amsterdam, p. 385-405.
Geophysical characteristics of dacite volcanism - the 1977-1978 eruption of Usu volcano, 1981
Yokoyama, I., Yamashita, H., Watanabe, H., and Okada, H., 1981, Geophysical characteristics of dacite volcanism - the 1977-1978 eruption of Usu volcano: Journal of Volcanology and Geothermal Research, v. 9, p. 335-358.
Alaska fisheries and fur industries in 1913, 1914
Evermann, B.W., 1914, Alaska fisheries and fur industries in 1913: Washington D.C., Government Printing Office, 172 p.
Aniakchak Crater, 1976
Trowbridge, Thelma, 1976, Aniakchak Crater: in Henning, R. A., Rosenthal, C. H., Olds, Barbara, and Reading, Ed, (eds.), Alaska's volcanoes, northern link in the ring of fire, Alaska Geographic, v. 4, n. 1, p. 71-73.
The Novarupta-Katmai eruption of 1912: Largest eruption of the twentieth century: Centennial perspectives, 2012
Hildreth, W., and Fierstein, J., 2012, The Novarupta-Katmai eruption of 1912: Largest eruption of the twentieth century: Centennial perspectives: U.S. Geological Survey Professional Paper 1791, 259 p., available at http://pubs.usgs.gov/pp/1791/ .
An evaluation of the effects of tourism on traditional activities - an ethnographic study for the Alagnak Wild River Area, 2013
Duer, D., and Evanoff, K., 2013, An evaluation of the effects of tourism on traditional activities - an ethnographic study for the Alagnak Wild River Area: Portland, O.R., Portland State University, 413 p.
Interconnection of magma sources beneath the Katmai volcanic system inferred from seismic tomography and petrology, 2023
Koulakov, I., Izbekov, P., Eichelberger, J., Al Arifi, N., and Qaysi, S.I., 2023, Interconnection of magma sources beneath the Katmai volcanic system inferred from seismic tomography and petrology: Journal of Volcanology and Geothermal Research v. 434, 107744. https://doi.org/10.1016/j.jvolgeores.2023.107744.
The evolution of Arctic permafrost over the last 3 centuries from ensemble simulations with the CryoGridLite permafrost model, 2024
Langer, M., Nitzbon, J., Groenke, B., Assmann, L.-M., Schneider von Deimling, T., Stuenzi, S. M., and Westermann, S., 2024, The evolution of Arctic permafrost over the last 3 centuries from ensemble simulations with the CryoGridLite permafrost model: The Cryosphere v. 18, no. 1, p. 365-385. https://doi.org/10.5194/tc-18-363-2024, 2024
Full-text PDF 6.3 MB The significance of volcanic ash in Greenland ice cores during the Common Era, 2023
Plunkett, G., Sigl, M., McConnell, J.R., Pilcher, J.R., and Chellman, N.J., 2023, The significance of volcanic ash in Greenland ice cores during the Common Era: Quaternary Science Reviews v. 301, 107936. https://doi.org/10.1016/j.quascirev.2022.107936
Full-text PDF 4.1 MB