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A new mechanism for caldera formation resulting from interactions between magmatic heat and cryospheric ice.

Research output: Contribution to conference - Without ISBN/ISSN Conference paper

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A new mechanism for caldera formation resulting from interactions between magmatic heat and cryospheric ice. / Tyson, Shelly; Wilson, Lionel; Gilbert, Jennifer et al.
2009. Paper presented at 40th Lunar and Planetary Science Conference, Woodlands, Texas, United States.

Research output: Contribution to conference - Without ISBN/ISSN Conference paper

Harvard

Tyson, S, Wilson, L, Gilbert, J & Lane, S 2009, 'A new mechanism for caldera formation resulting from interactions between magmatic heat and cryospheric ice.', Paper presented at 40th Lunar and Planetary Science Conference, Woodlands, Texas, United States, 23/03/09 - 27/03/09. <http://www.lpi.usra.edu/meetings/lpsc2009/pdf/1716.pdf>

APA

Tyson, S., Wilson, L., Gilbert, J., & Lane, S. (2009). A new mechanism for caldera formation resulting from interactions between magmatic heat and cryospheric ice.. Paper presented at 40th Lunar and Planetary Science Conference, Woodlands, Texas, United States. http://www.lpi.usra.edu/meetings/lpsc2009/pdf/1716.pdf

Vancouver

Tyson S, Wilson L, Gilbert J, Lane S. A new mechanism for caldera formation resulting from interactions between magmatic heat and cryospheric ice.. 2009. Paper presented at 40th Lunar and Planetary Science Conference, Woodlands, Texas, United States.

Author

Tyson, Shelly ; Wilson, Lionel ; Gilbert, Jennifer et al. / A new mechanism for caldera formation resulting from interactions between magmatic heat and cryospheric ice. Paper presented at 40th Lunar and Planetary Science Conference, Woodlands, Texas, United States.2 p.

Bibtex

@conference{5b3b287fca0943b6aca03ecc9409b0e8,
title = "A new mechanism for caldera formation resulting from interactions between magmatic heat and cryospheric ice.",
abstract = "It is generally accepted that volcanic caldera formation takes place when supporting material is removed from below. There is much field and laboratory evidence to suggest that this material is removed via magma loss from a shallow reservoir to feed an eruption or intrusion (e.g. [1, 2 and 3]). There is nothing to suggest however that the supporting material must be magma.Calculations show that if the ice held within a cryosphere were melted, by a hot magmatic intrusion, compaction of the remaining rock could take place and cause collapse of a coherent overlying block, analogous to conventional caldera collapse. Furthermore this process is likely to occur at a variety of smaller scales in a similar fashion to kettle-hole formation on Earth.Hecates Tholus, Mars (31.73° N 150° E) has many pits, channels and depressions of ambiguous origin in addition to well-studied fluvial channels (Fig 1). We explore the hypothesis that many of these features were formed by this ice-melting mechanism and that such melting could have influenced the formation of one or more of the calderas themselves.",
author = "Shelly Tyson and Lionel Wilson and Jennifer Gilbert and Stephen Lane",
year = "2009",
language = "English",
note = "40th Lunar and Planetary Science Conference ; Conference date: 23-03-2009 Through 27-03-2009",

}

RIS

TY - CONF

T1 - A new mechanism for caldera formation resulting from interactions between magmatic heat and cryospheric ice.

AU - Tyson, Shelly

AU - Wilson, Lionel

AU - Gilbert, Jennifer

AU - Lane, Stephen

PY - 2009

Y1 - 2009

N2 - It is generally accepted that volcanic caldera formation takes place when supporting material is removed from below. There is much field and laboratory evidence to suggest that this material is removed via magma loss from a shallow reservoir to feed an eruption or intrusion (e.g. [1, 2 and 3]). There is nothing to suggest however that the supporting material must be magma.Calculations show that if the ice held within a cryosphere were melted, by a hot magmatic intrusion, compaction of the remaining rock could take place and cause collapse of a coherent overlying block, analogous to conventional caldera collapse. Furthermore this process is likely to occur at a variety of smaller scales in a similar fashion to kettle-hole formation on Earth.Hecates Tholus, Mars (31.73° N 150° E) has many pits, channels and depressions of ambiguous origin in addition to well-studied fluvial channels (Fig 1). We explore the hypothesis that many of these features were formed by this ice-melting mechanism and that such melting could have influenced the formation of one or more of the calderas themselves.

AB - It is generally accepted that volcanic caldera formation takes place when supporting material is removed from below. There is much field and laboratory evidence to suggest that this material is removed via magma loss from a shallow reservoir to feed an eruption or intrusion (e.g. [1, 2 and 3]). There is nothing to suggest however that the supporting material must be magma.Calculations show that if the ice held within a cryosphere were melted, by a hot magmatic intrusion, compaction of the remaining rock could take place and cause collapse of a coherent overlying block, analogous to conventional caldera collapse. Furthermore this process is likely to occur at a variety of smaller scales in a similar fashion to kettle-hole formation on Earth.Hecates Tholus, Mars (31.73° N 150° E) has many pits, channels and depressions of ambiguous origin in addition to well-studied fluvial channels (Fig 1). We explore the hypothesis that many of these features were formed by this ice-melting mechanism and that such melting could have influenced the formation of one or more of the calderas themselves.

M3 - Conference paper

T2 - 40th Lunar and Planetary Science Conference

Y2 - 23 March 2009 through 27 March 2009

ER -