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Global GIS : volcanoes of the world ; volcano basic data

Identification Information
Citation
Originator
Smithsonian Institution. Global Volcanism Program
Originator
American Geological Institute
Originator
Geological Survey (U.S.)
Originator
Environmental Systems Research Institute (Redlands, Calif.)
Publication Date
2003
Title
Global GIS : volcanoes of the world ; volcano basic data
Geospatial Data Presentation Form
vector digital data
Collection Title
Global GIS : global coverage
Publication Information
Publication Place
[Alexandria, VA]
Publisher
American Geological Institute
Online Linkage
https://hgl.harvard.edu/catalog/harvard-glb-volc
Abstract
This datalayer is point coverage containing basic geographic and geologic information for worldwide volcanoes thought to have been active in the last 10,000 years (Holocene). The data is a collection of information by Smithsonian Institution volcanologists summarizing 1,509 volcanoes and this version of the data set was published as part of the USGS Global GIS : global coverage database. The data was adapted from Simkin and Siebert, 1994 "Volcanoes of the World: an Illustrated Catalog of Holocene Volcanoes and their Eruptions" and produced digitally by the Smithsonian Institution's Global Volcanism Program. The data include a unique volcano number, volcano name, location, latitude and longitude, summit elevation, volcano type, status, and the time range of the last recorded eruption. More detailed descriptions of the data elements, plus more information on the volcanoes and their eruptions, can be found below and in "Volcanoes of the World" (Simkin and Siebert, 1994). The book provides a discussion of the many cautions that are so easily stripped away from an electronic database, such as the incomplete and uneven nature of the historical record, even in this century, and the large uncertainties surrounding many older eruption dates. The accuracy of the record varies enormously from one region to another (and one century to another), and the sea-floor volcanism that dominates our planetary magma budget is scarcely represented in this data set. The basic building block of the Smithsonian's volcano database is the "Catalog of Active Volcanoes of the World" (CAVW), a series of regional volcano catalogs published by IAVCEI beginning in 1951. The listings are not intended to be a comprehensive bibliography of references for a particular volcano or region, but represent those references that are cited as the sources of the volcano and eruption data in the CAVW. Several other global compilations have been helpful: among them are IAVCEI data sheets of post-Miocene volcanoes (1975-80), Volcano Letter reports of the U S Geological Survey from 1926-1955 (compiled in Fiske et al., 1987), independent compilations by Latter (1975) and Gushchenko (1979), and a caldera compilation by Newhall and Dzurisin (1988). Major sources of eruption data subsequent to or supplementing the CAVW can be found in a series of annual summaries by Gustav Hantke published between 1939 and 1962 (mostly in the IAVCEI publication Bulletin of Volcanology), and annual eruption compilations by the Volcanological Society of Japan (1960-96) and Smithsonian Institution reports (since 1968) in various formats, compiled in McClelland et al., (1985) and in the Activity Reports section of the Smithsonian Institution, Global Vulcanism website (Venzke et al., 2002-). The data sources referenced focus almost exclusively on Holocene volcanism and emphasize papers on volcanic stratigraphy and physical volcanology. Abstracts are typically not referenced unless they contain significant data not in other sources. As with the Georef bibliographic database, diacritical marks are not used.
Purpose
Compile and classify the known "volcanoes" on Earth.
Supplemental Information
Portions of this metadata are taken directly from the American Geological Institute, Global GIS, Web pages: http://www.agiweb.org/pubs/globalgis/
Temporal Extent
Currentness Reference
publication date
Time Instant
2003
Bounding Box
West
-179.970000
East
179.620000
North
88.270000
South
-78.250000
Theme Keyword
Volcanoes
Volcanic eruptions
Theme Keyword Thesaurus
LCSH
ISO Topic Category
geoscientificInformation
Place Keyword
Earth
Northern Hemisphere
Southern Hemisphere
Eastern Hemisphere
Western Hemisphere
Africa
Asia
Australia
Europe
North America
South America
Polar Regions
Place Keyword Thesaurus
LCSH
Temporal Keyword
Access Restrictions
None
Use Restrictions
Several requests exist for users of this data file: 1) Please let us [the Smithsonian Institution] know of corrections or additions (with references or reprints if possible) that will help us improve the data file. 2) Please acknowledge "Smithsonian Institution, Global Volcanism Program" as the data source in any disseminated use of the data file. 3) We [the Smithsonian Institution] would appreciate a copy of whatever published work results from your use of the data. For further copyright and use constraints information please visit the Smithsonian Institution Web site: http://www.si.edu/copyright/ or contact the Smithsonian's Office of Product Development and Licensing: RightsManager@retail.si.edu
Status
Complete
Maintenance and Update Frequency
As needed
Point of Contact
Contact Organization
Smithsonian Institution, Global Volcanism Program
Delivery Point
Global Volcanism Program, Department of Mineral Sciences
Delivery Point
National Museum of Natural History - Room E-421
Delivery Point
MRC 0119, PO Box 37012, Smithsonian Institution
City
Washington
State
DC
Postal Code
20013-7012
Country
USA
Contact Facsimile Telephone
202-357-2476
Contact Electronic Mail Address
gvp@si.edu
Credit
Please acknowledge "Smithsonian Institution, Global Volcanism Program" as the data source in any disseminated use of the data file.
Native Data Set Environment
Microsoft Windows 2000 Version 5.0 (Build 2195) Service Pack 4; ESRI ArcCatalog 9.1.0.722
Collection
Originator
American Geological Institute
Originator
Geological Survey (U.S)
Originator
Environmental Systems Research Institute (Redlands, Calif.)
Originator
Hearn, Paul P.
Publication Date
2003
Title
Global GIS : global coverage
Geospatial Data Presentation Form
digital data
Series Information
Series Name
U.S. Geological Survey digital data series
Issue Identification
DDS-62A-H
Publication Information
Publication Place
[Alexandria, VA]
Publisher
American Geological Institute
Other Citation Details
1 DVD-ROM; Developed by the U.S. Geological Survey; Published by the American Geological Institute; by P. Hearn ... [et al.].
Data Quality Information
Attribute Accuracy Report
References are linked directly to data in the Volcano Reference File. This sometimes results in apparently incorrect citations in lists of data sources for a volcano or a region. Discussion of another volcano or eruption (sometimes far from the one that is the subject of the manuscript) may produce a citation that is not at all apparent from the title. Alert readers will note a backlog of uncited references for publications in recent years, which we will continue to address. Please let us [the Smithsonian Institute Global Volcanism Program) know of corrections or additions (with references or reprints if possible) that will help us improve the data file.
Logical Consistency Report
Unknown
Completeness Report
From the Global Volcanism Program Frequently Asked Questions Web page: "What is a volcano? One of the most difficult problems of standardization has been the varying usage of the word "volcano." Definitions of "volcano" range from individual vents, measured in meters, through volcanic edifices measured in kilometers or tens of kilometers, to volcanic fields measured in hundreds of kilometers. In a database compilation, the disadvantage of the narrowest definition is not so much the multiplicity of names introduced, as the dismembering of a single volcanic plumbing system's history into apparently unrelated separate records. The interiors of ancient volcanoes, now eroded and exposed for geologic study, show us that most subsurface magma chambers--the suppliers of lavas to overlying volcanoes--are at least several kilometers in diameter. We also know that many contemporary volcanoes grow by additions from countless flank vents as well as activity at a central crater. Consequently, we have tended to group closely spaced "volcanoes" such as the historical vents of the Canary Islands (many listed as separate volcanoes in the Catalog of Active Volcanoes of the World) by the major volcanic edifice on which they are found. Volcanoes listed here are rarely closer than 10 km to their nearest neighbor, and are commonly separated by at least 20 km. Another problem is simply the identification of volcanoes. Prominent, steaming cones are easy to recognize, but water, ice, erosion, collapse processes, or dense vegetation can mask very dangerous volcanoes. For example, Lake Taupo, in the center of New Zealand's North Island, is beautifully tranquil, with no obvious features alerting non-geologists to its particularly violent history. In the Alaskan summer of 1975, two volcanologists traced an ever-thickening ash layer to a vent now covered by the Hayes Glacier, and a "new" volcano was added to the NE end of the Aleutian arc. Also in Alaska, five decades passed before the true source of this century's largest eruption was recognized: subsurface magma connections led to prominent collapse of Mount Katmai in 1912, and this was assumed to be the eruption's source until careful fieldwork showed it to be Katmai's inconspicuous neighbor, Novarupta. These examples illustrate why the listings generated from this database must be recognized as incomplete. Inclusion in this compilation may depend on thoroughness of mapping--quite variable through the world's volcanic regions--and the most dangerous volcanoes may be those not yet recognized."
Horizontal Positional Accuracy Report
Geographic coordinates are listed in decimal parts of a degree. This facilitates both computer manipulation of data and rapid estimation of distances between points (one degree of latitude being equal to 111 km). To retain some indication of the accuracy of original locations, when converting from minutes and seconds we have listed three digits to the right of the decimal point only where seconds were originally specified. We list two digits if only degrees and minutes were given in the original (e.g., 71???41' = 71.68??? whereas 71???41' 01" = 71.684???). Readers should also beware of obviously generalized locations such as X.00??? or Y.50???. When different references give different positions for the same volcano, we attempt to determine which is most reliable, and list that location here. For some regions, where our archive of topographic maps permits, we have obtained more precise locations than given in older sources. Maps for the Kurils and Kamchatka, for example, have permitted correction of deliberately mislocated volcano positions that were a cold war artifact. Note that some locations are the center point of broad volcanic fields; these are flagged by an "*" after the latitude. Furthermore, even at individual volcanoes the coordinates given do not necessarily match the eruption site. Tens of kilometers may separate eruptive centers of a single volcano, particularly in large caldera complexes and rift settings.
Lineage
Source
Originator
Smithsonian Institution. Global Volcanism Program
Publication Date
2000-
Title
Global Volcanism Program : volcanoes of the world
Geospatial Data Presentation Form
document
Publication Information
Publication Place
Washington, D.C.
Publisher
Smithsonian Institution Global Volcanism Program
Other Citation Details
Latest data available for download from the Smithsonian Institution's Global Volcanism Program Web site.
Online Linkage
http://www.volcano.si.edu/gvp/world/index.cfm
Type of Source Media
online
Source Temporal Extent
Time Period Information
Range of Dates/Times
Beginning Date
2000
Ending Date
unknown
Source Currentness Reference
publication date
Contribution
Online updated version of the dataset
Source
Originator
Simkin, Tom.
Originator
Siebert, Lee.
Originator
Smithsonian Institution. Global Volcanism Program.
Publication Date
1994
Title
Volcanoes of the world.
Edition
2nd ed.
Geospatial Data Presentation Form
document
Publication Information
Publication Place
Tuscon, Ariz.
Publisher
Geoscience Press
Type of Source Media
paper
Source Temporal Extent
Time Period Information
Single Date/Time
Calendar Date
1994
Source Currentness Reference
publication date
Contribution
Paper catalog of volcanoes of the world.
Source
Originator
International Association of Volcanology and Chemistry of the Earth's Interior.
Originator
International Volcanological Association.
Publication Date
1951-1975
Title
Catalogue of the active volcanoes of the world, including solfatara fields.
Geospatial Data Presentation Form
document
Publication Information
Publication Place
Rome ; Naples, Italy
Publisher
International Association of Volcanology ; International association of volcanology and chemistry of the earth's interior
Other Citation Details
Issued in regional volumes.
Type of Source Media
paper
Source Temporal Extent
Time Period Information
Range of Dates/Times
Beginning Date
1951
Ending Date
1975
Source Currentness Reference
publication date
Contribution
Paper catalog of volcanoes of the world.
Spatial Data Organization Information
Direct Spatial Reference Method
Vector
Point and Vector Object Information
SDTS Terms Description
SDTS Point and Vector Object Type
Entity point
Point and Vector Object Count
1509
Spatial Reference Information
Horizontal Coordinate System Definition
Geographic
Latitude Resolution
0.000001
Longitude Resolution
0.000001
Geographic Coordinate Units
Decimal degrees
Geodetic Model
Horizontal Datum Name
North American Datum of 1927
Ellipsoid Name
Clarke 1866
Semi-major Axis
6378206.400000
Denominator of Flattening Ratio
294.978698
Vertical Coordinate System Definition
Altitude System Definition
Altitude Datum Name
Unknown
Altitude Resolution
1.000000
Altitude Distance Units
Unknown
Altitude Encoding Method
Explicit elevation coordinate included with horizontal coordinates
Entity and Attribute Information
Entity Type
Entity Type Label
Global GIS Volcanoes
Entity Type Definition
Points representing volcanoes
Entity Type Definition Source
None
Attributes
ELEV
Summit elevation in meters (-6000 to 6887 meters)
Definition Source
CAVW
Shape
Feature geometry (Coordinates defining the features.)
Definition Source
ESRI
STATUS
Type of evidence for Holocene activity. (Character field.)
Definition Source
CAVW [See entity and attribute overview section].
NUMBER_
Unique identification number based on the scheme (Number field.)
Definition Source
CAVW
NAME_
Name given to volcano. (Character field.)
Definition Source
CAVW
LON
Longitude given in decimal degrees (-179.97 to 179.62 decimal degrees)
Definition Source
CAVW
LOCATION
Geographic and/or political area (Character field.)
Definition Source
CAVW
LAT
Latitude given in decimal degrees. (-78.25 to 88.27 decimal degrees)
Definition Source
CAVW
TYPE_
Volcano morphology. (Character field.)
Definition Source
CAVW See entity and attribute overview section].
TIME_FRAME
Code indicating whether dated eruptions have been recorded, and the time period of the volcano's last known eruption
?
Uncertain Holocene eruption
D1
Last known eruption 1964 or later
D2
Last known eruption 1900-1963
D3
Last known eruption 1800-1899
D4
Last known eruption 1700-1799
D5
Last known eruption 1500-1699
D6
Last known eruption A.D. 1-1499
D7
Last known eruption B.C. (Holocene)
Q
Quaternary eruption(s) with the only known Holoceneactivity being hydrothermal
U
Undated, but probable Holocene eruption
Definition Source
CAVW
MARC.GLB_VOLC.FID
Internal feature number. (Sequential unique whole numbers that are automatically generated.)
Definition Source
ESRI
SHAPE
Feature geometry. (Coordinates defining the features.)
Definition Source
ESRI
Entity and Attribute Overview
Volcano Number The volcano numbering system, developed by the Catalog of Active Volcanoes of the World (CAVW) in the late 1930s and used in all their catalogs, is geographic and hierarchical. The first two numerals identify region, the next two identify subregion, and the last two or three (after the hyphen) identify individual volcanoes in that subregion. Original CAVW volcano numbers have been retained, where possible, to aid cross-referencing, but this has required, for the many volcanoes added since CAVW publication, the interpolation of 3-digit volcano numbers between 2-digit CAVW numbers. Volcanoes bearing numbers identical to those used by the CAVW carry an "=" symbol at the end of the number to facilitate reference to the CAVW for fuller descriptions. When we have added a volcano between those already numbered, we have added a third numeral. Thus Lipari, between Stromboli (0101-04=) and Vulcano (0101-05-), is given the number 0101-041 rather than the next available two-digit number at the end of the Italian subregion. This scheme permits natural geographic sequencing of volcanoes while retaining original CAVW numbering. Letters have been added at the end of a very few individual volcano numbers to designate volcanoes thought likely to be interconnected yet sufficiently separated that one cannot be clearly designated a subfeature of another. The grouping is shown by using the same volcano number in each case, with letters at the end of each individual number in the group. When adding numbers in regions not previously numbered by the CAVW, and when renumbering in regions such as the Canary Islands and the western United States, we have used only two numerals for the individual volcano number but have designated the fact that it cannot be found under this number in the CAVW by adding a "-" in the last place. Crater Lake, in the Cascade Range of Oregon, for example, is numbered 1202-16- here, but was not included in the CAVW. Volcano Name With few exceptions, we have used the names listed by the compilers of the CAVW, the contributors to the IAVCEI post-Miocene data sheets, and individual volcanologists reporting on additional volcanoes. We have preferred broader island names, locatable on standard maps, rather than crater names locally used to identify the full island volcano, and we have dropped modifiers, such as "Mount," when they seemed unnecessary. We have used square brackets, however, to indicate alternative names that are widely encountered in the literature (e.g. "Cerro Azul [Quizapu]" in Chile). For Japanese volcanoes we have listed the more widely used Hepburn style of spelling. Readers familiar with older spellings of Indonesian names will note that newer official names are used here, so that TJ, DJ, J and OE appear as C, J, Y, and U, respectively. We have excluded special characters from other languages that would strain our already-overburdened computers. A few names have also been changed from the CAVW to reflect the broader time coverage of this compilation. Historically active features that are clearly part of a larger feature active in Holocene time have been listed under the larger feature. For example, the CAVW lists volcano number 0603-31= as Bromo; however, Bromo is but one of several youthful features in Tengger caldera, so we have used the caldera name. An extension of the time coverage problem is the grouping problem mentioned above. Amboy, a solitary cinder cone 200 km east of Los Angeles, is entered as a single volcano, and so is the Michoacan-Guanajuato Field, made up of nearly 1,000 cinder cones dotting a 200 x 200 km area in Mexico. Clearly not all "volcanoes" are equal, and caution must be used in any serious counting of them. Location The location consists of the "subregion" designated by the CAVW compilers (and identified by the third and fourth digits of the volcano number, but we have added a more general location name where useful for identification). Latitude and Longitude Geographic coordinates are listed in decimal parts of a degree. This facilitates both computer manipulation of data and rapid estimation of distances between points (one degree of latitude being equal to 111 km). To retain some indication of the accuracy of original locations, when converting from minutes and seconds we have listed 3 digits to the right of the decimal point only where seconds were originally specified. We list 2 digits if only degrees and minutes were given in the original (e.g., 71???41' = 71.68??? whereas 71???41' 01"= 71.684???). Readers should also beware of obviously generalized locations such as X.00??? or Y.50???. When different references give different positions for the same volcano, we attempt to determine which is most reliable, and list that location here. For some regions, where our growing archive of topographic maps permits, we have obtained more precise locations than given in older sources. Newly obtained maps for the Kuriles and Kamchatka, for example, have permitted correction of deliberately mislocated volcano positions that were a cold war artifact. Note that some locations are the center point of broad volcanic fields, and that even at individual volcanoes the coordinates given do not necessarily match the eruption site. Tens of kilometers may separate eruptive centers of a single volcano, particularly in large caldera complexes and rift settings. Distribution of the world's volcanoes with respect to latitude has gained wide interest because of the relationship between large volcanic eruptions and climate. Major explosive eruptions drive volcanic ash and gas tens of kilometers into the stratosphere where, because fine ash and aerosol particles settle slowly and are not washed out by rain, they may be distributed around the globe by stratospheric circulation. For months or years before settling back to Earth, then, this layer of volcanic aerosol acts as a solar radiation filter, lowering temperatures on the Earth below it. The extent to which this process has affected global climate in the past is a matter of considerable scientific debate, but the fact that individual eruptions can affect climate is established (the catastrophic eruption of Indonesia's Tambora in 1815, for example, contributed to a lowering of global temperatures that brought June snow-storms to New England and widespread crop failure to northern latitudes). The Earth's rotation strongly influences stratospheric circulation patterns and therefore any concentration of the world's volcanoes by latitude is important in assessing their effect on global climate. Two thirds of the volcanoes are in the northern hemisphere and only about one fifth are between 10???S and the South Pole. The northern hemisphere concentration reflects the fact that two-thirds of the world's land area is also north of the equator, but nevertheless indicates the greater vulnerability of the northern hemisphere to volcanically induced climate change. The most northerly volcano in our list is an unnamed submarine volcano in the Arctic Ocean only 192 km from the North Pole. Three eruptions have been attributed to this site. The next most northerly volcano, on Jan Mayen island and 2104 km from the pole, has been recently quite active with vigorous eruptions in 1970 and early 1985. The southernmost historically active volcano is Mount Erebus, 1387 km from the South Pole on Ross Island, Antarctica. This volcano was erupting violently when first seen by Ross, in 1841, and is active today with a molten lava lake that has been circulating in its summit crater since at least 1972. The many young cinder cones of the Royal Society Range, 80 km closer to the pole are probably Holocene, and local ash layers have been found in glaciers, but no eruptions have been dated. No significant concentration of volcanoes by longitude is obvious, but over 1000 volcanoes (or two-thirds of those listed) lie around the Pacific Ocean margin forming the well known "Ring of Fire." Linear belts of volcanoes are a striking feature of the planet and they reflect, in most cases, convergence of the major tectonic plates that make up the Earth's outer shell. These vast plates, moving at speeds of only a few centimeters per year, form a shifting jig-saw puzzle with the major earthquake and volcano belts marking the unrest at plate boundaries. Where plates converge, with the thinner plate normally being thrust down under the thicker, a line of volcanoes grows above (and as a result of) the under-thrusting. Because this type of volcanism is normally both explosive and near (if not on) land, we have a reasonably complete listing of these volcanoes (approximately two-thirds of this file). The spreading apart of major plates, however, is characterized by the relatively nonexplosive outpouring of fluid lava and commonly takes place one or more kilometers below the surface of the ocean. Consequently we have a very incomplete record of this important type of volcanism. Rift volcanism forms only 5% of our eruption file and is dominated by those few regions, such as East Africa and Iceland, where the spreading apart of plates takes place above sea level. The remainder of our file--less than a tenth of the total--represents volcanism within major plates rather than at their boundaries. This takes place when deep "hot spots" penetrate the overlying crust and old volcanic products are carried slowly away from the volcanic center by the moving plate. Although our record of intraplate volcanism is probably better than that for the volcanism of spreading ocean ridges, we no doubt miss many examples, particularly from the sea floor. Elevation Elevation of each volcano's highest point is listed in meters above or below sea level. Elevation for the same volcano may differ because of different surveying techniques or because of volcanological changes (e.g. the 400 m change in Mount St. Helens' summit height in 1980). As with latitude and longitude, when separate values for the same feature appear in different references we display here the one that seems to be most reliable. When unable to resolve a difference any other way, we normally display the more recent figure. Most elevations, both in the CAVW and original references, are given in meters, but when we have had to convert from other units we have attempted to retain a measure of the original's accuracy by rounding the conversion to the same number of significant figures as in the original. Thus a 2,600 ft elevation, apparently rounded to the nearest 100 ft, is listed here as 790 m rather than the 792 m figure that is the exact metric equivalent (but implies more accuracy than in the original measurement). Less than 4% of the listed volcanoes, most of them submarine, have elevations unknown to us. Submarine volcano elevations (or depths) are particularly unreliable because changes are often rapid, dramatic, and unrecorded. We normally list the most recent elevation when several are given, but caution should be used with all submarine volcano elevations. Roughly 30% of the volcanoes in our list are within 1,000 m of sea level, roughly 60% are within 2,000 m and about four-fifths are within 3,000 m of sea level. Less than 100 volcanoes have elevations above 5,000 m (16,400 ft): most of these are in the South American Andes and nearly two-thirds of the total are in that chain's central segment (15-28???S). The highest volcano with historical eruptions is Llullaillaco (volcano number 1505-11=) in the northern Chilean Andes. Its elevation is 6,739 m and three eruptions were recorded there in the second half of the last century. Active fumaroles, however, mark the summit crater of Nevado Ojos del Salado, 267 km to the south of, and 148 m higher than, Llullaillaco. The youthful nature of Nevado Ojos del Salado suggests that its lack of historical eruptions stems only from its remote location, and it is rightfully the world's highest volcano. The only higher mountain in the Americas, Argentina's Aconcagua at 7,021 m, was listed as active by Darwin during the voyage of the Beagle, but Chilean colleagues tell us that the mountain is not a volcano and its height results from imbricate thrust faulting. The deepest submarine volcano in our list has less significance because the record is so poor. Seawater not only hides eruptions from view, but its weight also provides enormous pressure on the deep-sea floor, inhibiting (and often prohibiting) the explosive release of volcanic gases that frequently calls attention to shallow submarine eruptions. A few historical reports, however, give some credence to explosive volcanism on the deep-sea floor: 1955 activity at 4000 m near Hawaii (1302-10=), 1865 activity at 4200 m west of the Azores (1801-04=), uncertain 1852 activity at 5300 m in the central mid-Atlantic (1805-04=), and an 1850 event at about 6000 m depth off Taiwan. Non-explosive volcanism regularly takes place at great depths on the ocean floor, as shown by photography of fresh volcanic features at depths of ~ 5 km in the Cayman Trough, Caribbean Sea, but our record of it is exceedingly scanty. Type (Morphology) Volcanoes come in a variety of shapes and sizes. Under the heading of type, we have attempted to characterize the morphology of each volcano. An individual volcano may be composed of a variety of landforms, such as when a stratovolcano is truncated by a caldera that is itself filled by lava domes and pyroclastic cones--but we show only the most prominent feature here. We have followed the CAVW entry in most cases, although little attempt has been made to standardize usage. Profiles are illustrated here, but the reader should consult a volcanological textbook for further description (and recognize that different volcanologists have used different terms for the same features). Interest in the landforms of other planets has prompted a more quantitative approach to the morphology of Earth's volcanoes. Lacking a standardized nomenclature, however, we have generally listed the volcano types as given in the various sources used in our compilation. Status This element states, essentially, the most persuasive reason for including each volcano in this compilation. A "historical" eruption, documented during or shortly after observation, is the best evidence for inclusion. We list more than 540 volcanoes with historical eruptions, the criterion used by many people terming a volcano "active." However, we have tried to provide more even coverage of the globe's volcanoes, many of which carry no written record until 80 centuries after the first historically documented eruption in our file (Central Turkey, in 6200 BC). To do this we have included 183 volcanoes with dated eruptions during the last 10,000 years, as determined by techniques, such as "Radiocarbon" dating. For volcanoes with different eruptions dated by different techniques, we have entered under Status the technique that seemed to confirm Holocene activity most certainly. We should mention, however, that the "Anthropology" status covers volcanoes with undated (but recent) activity described in native legends as well as activity dated by buried artifacts. The remaining Status categories cover the many volcanoes (about half of our file) for which Holocene eruptions have not been dated, but are either likely or possible. These status categories will be discussed in order of decreasing certainty. First in certainty for undated eruptions comes the variety of general evidence lumped together under "Holocene" status. These locations, although without dated products, are virtually certain to have been active in postglacial time. Evidence includes: (1) volcanic products overlying latest Pleistocene glacial debris, (2) youthful volcanic landforms in areas where erosion should have been pronounced in many thousands of years, and (3) vegetation patterns that would have been far richer if the volcanic substrates were more than a few thousand (or hundred) years old. We have included in this category volcanoes mapped by original authors simply as "Holocene" or "postglacial." Some subjectivity is involved in this assignment, and the compiler is dependent upon the field experience of the original author. Many early investigators, unaware of slow erosion rates in arid regions, described lava flows as "extremely fresh, probably erupted within the last few hundred or few thousand years," but later radiometric dating has shown them to be Pleistocene or even older. We have generally required strong evidence for entry under this category, but more than 500 volcanoes bear "Holocene" status in our file, and roughly another 100 (with distinctly less certainty) are identified as "Holocene?" (marked with a query symbol). Many volcanoes with obviously recent, but undated, eruptions are still visibly hot, as evidenced by surface thermal features displayed in the Status category. "Fumarolic" locations are those characterized by steam and volcanic gas, or fume, reaching the surface. Temperatures are near the boiling point of water and a substantial supply of groundwater is necessary. Previously we used the word "Solfataric" for Status when sulfur dominated the volcanic gases, but we have since encountered inconsistencies with this usage and have combined it with "Fumarolic" here. When the volume of water is large compared to steam and gas, however, the words "Hot springs" are used. A "Fumarolic" or "Hot springs" status is assigned, however, only where we have seen no explicit evidence for Holocene eruptive activity. Our least certain Status category, "Uncertain", is used for volcanoes with possible Holocene activity, but with sufficiently questionable documentation that we wanted to draw attention to that uncertainty. These entries include mariner's equivocal reports of submarine volcanism and volcanoes known only by uncertain reports of historical activity (with no other evidence of Holocene eruptions). One additional element must also be mentioned here as uncertain. We have followed the CAVW in including some thermal features, such as fumarolic fields, despite absence of other evidence for their Holocene volcanism. In fact, some areas, such as the Valles and Long Valley calderas in the western United States, show good evidence precluding eruptions in the last 10,000 years (but equally good evidence of still-molten magma below the surface). For about two dozen such volcanoes the word "Pleistocene-" precedes the appropriate thermal feature listed above, including the designation "Pleistocene-Geysers" used to identify uncommon variations of hot springs from which steam and water are periodically erupted. Although many thermal features require only a high local heat flow and groundwater, we have not included such features unless they are clearly related to volcanism. Finally, we should comment on the "youthful" volcanoes that we have not included in the file. A volcano mapped as "Quaternary" would not be entered unless more specific Holocene age data were available. When a group of volcanoes is listed in a region of "Pleistocene-Holocene volcanism", we have entered only those for which Holocene evidence is available. Volcanoes listed as Holocene, or "active", in previous compilations, but later found to be Pleistocene or older, have also been excluded, as have a few "volcanoes", well established in the literature, but later found to be misidentifications. In summary, the Status category conveys the following hierarchical progression from high to low certainty of Holocene volcanism: (1) "Historical," (2) dated eruptions based on a spectrum of techniques from "Hydrophonic" through "Radiocarbon" to "Anthropology", which is transitional to (3) "Holocene," (4) thermal features such as "Fumarolic", (5) "Uncertain", and (6) thermal features preceded by the word "Pleistocene-." Any entry can (and probably does) carry evidence to be found under lower levels of this hierarchy, but we have entered the highest Status category indicated by the data known to us. Furthermore, the Status listed is that of the most recent eruptive activity. A major Pleistocene center with only a single Holocene flank vent, for example, would have a "Holocene" status. Time Frame D1 = Last known eruption 1964 or later D2 = Last known eruption 1900-1963 D3 = Last known eruption 1800-1899 D4 = Last known eruption 1700-1799 D5 = Last known eruption 1500-1699 D6 = Last known eruption A.D. 1-1499 D7 = Last known eruption B.C. (Holocene) U = Undated, but probable Holocene eruption ? = Uncertain Holocene eruption Q = Quaternary eruption(s) with the only known Holocene activity being hydrothermal This code enables mapmakers to identify volcanoes in groups of increasing recency (and certainty) of eruptions. For example, for all volcanoes that have erupted in this century, choose D1 and D2, and for all with eruptions since 1 A.D. choose D1 through D6. Remember, however, that many volcanoes designated by a U (Undated) in regions with a short historical record have had unrecorded eruptions in the past few thousand years (perhaps even few hundred years). Volcanoes designated by D6, D7, or Q, include: (1) volcanoes with reasonably complete records yet no known eruptions for hundreds or thousands of years; and (2) poorly studied volcanoes with undocumented younger eruptions. The first set (D1, or 1964 to present) was selected to coincide with the USGS global earthquake dataset that spans the same time interval. Usage of "Volcano" One of the most difficult problems of standardization has been the varying usage of the word "volcano." Definitions of "volcano" range from individual vents, measured in meters, through volcanic edifices measured in kilometers or tens of kilometers, to volcanic fields measured in hundreds of kilometers. In a compilation such as this one, the disadvantage of the narrowest definition is not so much the multiplicity of names introduced, as the dismembering of a single volcanic plumbing system's history into apparently unrelated separate records. The interiors of ancient volcanoes, now eroded and exposed for geologic study, show us that most subsurface magma chambers--the suppliers of lavas to overlying volcanoes--are at least several kilometers in diameter. We also know that many contemporary volcanoes grow by additions from countless flank vents as well as activity at a central crater. Consequently, we have tended to group closely spaced "volcanoes" such as the historical vents of the Canary Islands (many listed as separate volcanoes in the CAVW) by the major volcanic edifice on which they are found. Volcanoes listed here are rarely closer than 10 km to their nearest neighbor, and are commonly separated by at least 20 km. Another problem is simply the identification of volcanoes. Prominent, steaming cones are easy to recognize, but water, ice, erosion, collapse processes, or dense vegetation can mask very dangerous volcanoes. For example, Lake Taupo, in the center of New Zealand's North Island, is beautifully tranquil, with no obvious features alerting non-geologists to its particularly violent history. In the Alaskan summer of 1975, two volcanologists traced an ever-thickening ash layer to a vent now covered by the Hayes Glacier, and a "new" volcano was added to the NE end of the Aleutian arc. Also in Alaska, 5 decades passed before the true source of this century's largest eruption was recognized: Subsurface magma connections led to prominent collapse of Mount Katmai in 1912, and this was assumed to be the eruption's source until careful fieldwork showed it to be Katmai's inconspicuous neighbor, Novarupta. These examples illustrate why the listings below must be recognized as incomplete. Inclusion in this compilation may depend on thoroughness of mapping--quite variable through the world's volcanic regions--and the most dangerous volcanoes may be those not yet recognized by compilers.
Entity and Attribute Detail Citation
See the Smithsonian Institution Global Volcanism Program Web site: http://www.volcano.si.edu/world/volcanocriteria.cfm
Distribution Information
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Shape
Distributor
Harvard Geospatial Library
Online Access
http://hgl.harvard.edu/
Name
Metadata Reference Information
Metadata Date
20060201
Metadata Contact
Contact Information
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Contact Organization
Harvard Geospatial Library
Contact Position
Geospatial Resources Cataloger
Contact Address
Address
Harvard University Library
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Office For Information Systems
Address
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City
Cambridge
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Postal Code
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Contact Voice Telephone
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Metadata Standard Name
FGDC Content Standards for Digital Geospatial Metadata
Metadata Standard Version
FGDC-STD-001-1998
Metadata Extensions
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http://www.esri.com/metadata/esriprof80.html
Profile Name
ESRI Metadata Profile
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