Jump to content

Cleopatra Patera: Difference between revisions

Edit links
From Wikipedia, the free encyclopedia
Browse history interactively
← Previous editNext edit →
Content deleted Content added
VisualWikitext
mos, ce
Eblamble (talk | contribs)
107 edits
rearranging
Line 13: Line 13:
[[File:Cleopatra Patera.png|thumb|900px|right|Zoomed in view extrapolated from Magellan imagery of Cleopatra patera, eastern flank of [[Maxwell Montes]] on [[Ishtar Terra]], Venus.]]
[[File:Cleopatra Patera.png|thumb|900px|right|Zoomed in view extrapolated from Magellan imagery of Cleopatra patera, eastern flank of [[Maxwell Montes]] on [[Ishtar Terra]], Venus.]]
'''Cleopatra Patera''' is a nearly circular [[Impact crater|double ring crater]] on [[Venus]], 2–3&nbsp;km deep and 105&nbsp;km in diameter.<ref name="Venusian Impact Craters">{{cite web | url=http://astro.if.ufrgs.br/solar/vencrate.htm | title=Venusian Impact Craters | publisher=Soler Views | year=1993 | accessdate=3 April 2014 | author=Hamilton, Calvin}}</ref><ref name="Volcanic or Impact?">{{cite conference | title=Cleopatra Patera, A Circular Structure in Maxwell Montes, Venus; Volcanic or Impact? | accessdate=28 February 2014 | author=Peterfreud, A.R. | editor=Head, J.W. | year=1984 | conference=Lunar and Planetary Science | location=Brown University | pages=641–642}}</ref><ref name="Tectonic or Magmatic">{{cite journal | title=Tectonic and Magmatic Models for the Origin of Cleopatra Patera | author=Nikishin, A.M. | journal=Lunar and Planetary Science Conference | year=1988 | pages=860–861}}</ref><ref name="Happy Solution">{{cite journal | title=Cleopatra Crater on Venus: Happy Solution of the Volcanic vs Impact Controversy | author=Basilevsky, A.T. et al | journal=Lunar and Planetary Science Conference | year=1991 | volume=XXII | issue=22 | pages=59–60}}</ref><ref name="Impact craters on Venus, Earth, and other planets">{{cite web | url=http://www.athenapub.com/venus1.htm | title=Impact craters on Venus, Earth, and other planets | publisher=Athena Review | year=2001 | accessdate=3 April 2014 | author=Athena Publications}}</ref><ref name="Ring Impact Craters on Venus">{{cite web | url=http://archive.org/stream/nasa_techdoc_19930005103/19930005103_djvu.txt | title=RINGED IMPACT CRATERS ON VENUS: AN ANALYSIS FROM MAGELLAN IMAGES | publisher=International Colloquium on Venus | year=1993 | accessdate=3 April 2014 | author=Alexopoulos, Jim and William McKinnon | pages=2–4}}</ref><ref name="Chapter 7: Venus">{{cite web | url=http://explanet.info/Chapter07.htm | title=Exploring the Planets | publisher=Prentice Hall | year=1995 | accessdate=3 April 2014 | author=Christiansen, Eric}}</ref> A [[patera]] is geologic feature defined as a crater formed by impact or volcanic origin. Cleopatra patera is unusual in that its origin was debated for twelve years.<ref name="Happy Solution" /><ref name="Volcanic or Impact?">{{cite conference | title=Cleopatra Patera, A Circular Structure in Maxwell Montes, Venus; <ref name=Volcanic or Impact? | accessdate=28 February 2014 | author=Peterfreud, A.R. | editor=Head, J.W. | year=1984 | conference=Lunar and Planetary Science | location=Brown University | pages=641–642}}</ref> A volcanic origin initially was supported due to non-impact geologic aspects, such as having a low rim, a surrounding plains-forming unit, and a non-concentric nature of its inner basin, as well as its proximity to [[Maxwell Montes]].<ref name="Happy Solution" /><ref name="Ring Impact Craters on Venus" /><ref name="Venera 15/16">{{cite journal | title=Cleopatra Patera on Venus: Venera 15/16 Evidence for a Volcanic Origin | author=Schaber, Gerald | journal=Geophysical Research Letters | year=1987 | month=January | volume=14 | issue=1 | pages=41–44}}</ref> However, as more recent missions to Venus improved in the clarity of topographic imagery from [[Arecibo]] radio telescope and [[Venera 15 and 16|Venera 15/16]] space crafts, the structures seen in the crater has cleared the scientific controversy and has been since identified as an impact crater.<ref name="Venusian Impact Craters" /><ref name="Happy Solution" /><ref name="Chapter 7: Venus"/><ref name="HIGH-RESOLUTION RADAR IMAGES OF VENUS">{{cite web | url=http://disc.sci.gsfc.nasa.gov/geomorphology/GEO_10/GEO_PLATE_P-11.shtml | title=HIGH-RESOLUTION RADAR IMAGES OF VENUS | publisher=NASA | year=2009 | accessdate=3 April 2014 | author=Kempler, Steven}}</ref><ref name="Venusian Craters ">{{cite web | url=http://www.mantleplumes.org | title=Venusian Craters and the Origin of Coronae | publisher=Lunar and Planetary Science | year=2004 | accessdate=4 April 2014 | author=Vita-Finzi, C et al}}</ref>
'''Cleopatra Patera''' is a nearly circular [[Impact crater|double ring crater]] on [[Venus]], 2–3&nbsp;km deep and 105&nbsp;km in diameter.<ref name="Venusian Impact Craters">{{cite web | url=http://astro.if.ufrgs.br/solar/vencrate.htm | title=Venusian Impact Craters | publisher=Soler Views | year=1993 | accessdate=3 April 2014 | author=Hamilton, Calvin}}</ref><ref name="Volcanic or Impact?">{{cite conference | title=Cleopatra Patera, A Circular Structure in Maxwell Montes, Venus; Volcanic or Impact? | accessdate=28 February 2014 | author=Peterfreud, A.R. | editor=Head, J.W. | year=1984 | conference=Lunar and Planetary Science | location=Brown University | pages=641–642}}</ref><ref name="Tectonic or Magmatic">{{cite journal | title=Tectonic and Magmatic Models for the Origin of Cleopatra Patera | author=Nikishin, A.M. | journal=Lunar and Planetary Science Conference | year=1988 | pages=860–861}}</ref><ref name="Happy Solution">{{cite journal | title=Cleopatra Crater on Venus: Happy Solution of the Volcanic vs Impact Controversy | author=Basilevsky, A.T. et al | journal=Lunar and Planetary Science Conference | year=1991 | volume=XXII | issue=22 | pages=59–60}}</ref><ref name="Impact craters on Venus, Earth, and other planets">{{cite web | url=http://www.athenapub.com/venus1.htm | title=Impact craters on Venus, Earth, and other planets | publisher=Athena Review | year=2001 | accessdate=3 April 2014 | author=Athena Publications}}</ref><ref name="Ring Impact Craters on Venus">{{cite web | url=http://archive.org/stream/nasa_techdoc_19930005103/19930005103_djvu.txt | title=RINGED IMPACT CRATERS ON VENUS: AN ANALYSIS FROM MAGELLAN IMAGES | publisher=International Colloquium on Venus | year=1993 | accessdate=3 April 2014 | author=Alexopoulos, Jim and William McKinnon | pages=2–4}}</ref><ref name="Chapter 7: Venus">{{cite web | url=http://explanet.info/Chapter07.htm | title=Exploring the Planets | publisher=Prentice Hall | year=1995 | accessdate=3 April 2014 | author=Christiansen, Eric}}</ref> A [[patera]] is geologic feature defined as a crater formed by impact or volcanic origin. Cleopatra patera is unusual in that its origin was debated for twelve years.<ref name="Happy Solution" /><ref name="Volcanic or Impact?">{{cite conference | title=Cleopatra Patera, A Circular Structure in Maxwell Montes, Venus; <ref name=Volcanic or Impact? | accessdate=28 February 2014 | author=Peterfreud, A.R. | editor=Head, J.W. | year=1984 | conference=Lunar and Planetary Science | location=Brown University | pages=641–642}}</ref> A volcanic origin initially was supported due to non-impact geologic aspects, such as having a low rim, a surrounding plains-forming unit, and a non-concentric nature of its inner basin, as well as its proximity to [[Maxwell Montes]].<ref name="Happy Solution" /><ref name="Ring Impact Craters on Venus" /><ref name="Venera 15/16">{{cite journal | title=Cleopatra Patera on Venus: Venera 15/16 Evidence for a Volcanic Origin | author=Schaber, Gerald | journal=Geophysical Research Letters | year=1987 | month=January | volume=14 | issue=1 | pages=41–44}}</ref> However, as more recent missions to Venus improved in the clarity of topographic imagery from [[Arecibo]] radio telescope and [[Venera 15 and 16|Venera 15/16]] space crafts, the structures seen in the crater has cleared the scientific controversy and has been since identified as an impact crater.<ref name="Venusian Impact Craters" /><ref name="Happy Solution" /><ref name="Chapter 7: Venus"/><ref name="HIGH-RESOLUTION RADAR IMAGES OF VENUS">{{cite web | url=http://disc.sci.gsfc.nasa.gov/geomorphology/GEO_10/GEO_PLATE_P-11.shtml | title=HIGH-RESOLUTION RADAR IMAGES OF VENUS | publisher=NASA | year=2009 | accessdate=3 April 2014 | author=Kempler, Steven}}</ref><ref name="Venusian Craters ">{{cite web | url=http://www.mantleplumes.org | title=Venusian Craters and the Origin of Coronae | publisher=Lunar and Planetary Science | year=2004 | accessdate=4 April 2014 | author=Vita-Finzi, C et al}}</ref>

==Crater impact model==
Most large impact craters do not have a central peak, yet have sharp rims bordered by asymmetrical radar bright [[ejecta blanket]]s, have multiple rims, are surrounded and partially filled by subsequent lava which creates a reduced apparent depth, have dark crater floors, and buries some ejecta.<ref name="Venusian Craters " /> By analyzing Magellan images, Cleopatra patera’s was found to be distorted in shape in that its noncircular inner ring is off center, but also that the outflow channel of lava moves from within the crater and reaches the top of the crater rim.<ref name="Ring Impact Craters on Venus" /> The interiors are radar dark and smooth in comparison to the surrounding plains.<ref name="Ring Impact Craters on Venus" /> From the image of Plate P-11 from Venera 15 and 16 shows that Cleopatra patera that was originally interpreted as a large caldera but has now been interpreted as a multi-ringed impact crater with a central peak.<ref name="HIGH-RESOLUTION RADAR IMAGES OF VENUS" /> Using photogeologic analysis, the floor of the crater has a shallow central depression resulting from [[subsidence]] of uplifted [[Mantle (geology)|mantle]] material from below due to "[[viscous]] relaxation".<ref name="Geology and Morphometry of Large Impact Craters of Venus">{{cite journal | title=Geology and Morphometry of Large Impact Craters of Venus | author=Basilevsky, A.T. et al | journal=Lunar and Planetary Science Conference | year=1994 | volume=XXV | pages=67–68}}</ref> This was found in Venusian craters larger than 70&nbsp;km in diameter by using altimetry data which shows surfaces with different elevations from the Magellan mission.<ref name="Geology and Morphometry of Large Impact Craters of Venus" />

===Patera geologic description===
Cleopatra patera has features in that of a double ring impact crater. The crater rim is scalloped and the center of the crater is steeply slanted down to a smooth dark crater floor.<ref name="Volcanic or Impact?" /><ref name="Happy Solution" /> A central peak is found in the center of the crater floor and outside the inner crater is masses of "coarse hummocky terrain." <ref name="Happy Solution" /> The plains surrounding the crater is smooth and bright, but there are some dark deposits around the topographic depressions just north of the crater.<ref name="Volcanic or Impact?" /><ref name="Happy Solution" /><ref name="Ring Impact Craters on Venus" /> These dark deposits are interpreted to be "[[Impact crater|shock-melt material]]" equivalent to ejecta blanket material; however, the dark deposits to the south are "ridge slopes."<ref name="Happy Solution" /> The outflow of material to the right of the crater is [[lava flows]] which have spilled from the bowl shape of the crater due to the impact hitting the steep side of Maxwell Montes, occurring at impact.<ref name="Happy Solution" /> When the [[magma chamber]] at the floor of Cleopatra erupted, subsidence occurred explaining the large depth of the crater.<ref name="Happy Solution" /><ref name="Geology and Morphometry of Large Impact Craters of Venus" />


==Original volcanic model==
==Original volcanic model==
Line 18: Line 24:
Prior to improved satellite imagery from the [[Magellan (spacecraft)|Magellan]] mission, the topography of Venus was interpreted from lower quality images received from [[radio telescopes]] and [[altimetry|altimetric]] data.<ref name="Tectonic or Magmatic" /> This data allowed for a misinterpretation of the crater; however, it is important to understand what was seen geometrically to explain why certain hypotheses withstood many years.<ref name="Volcanic or Impact?" /> It was found that the topographic elevation on Maxwell Montes resulted from a combination of [[Compression fracture|horizontal compression]] and vertical [[crustal thickening]], which in combination allowed for the [[Crust (geology)|lower crust]] to be partially melted, so long as the crustal thickness exceeds 40&nbsp;km.<ref name="Tectonic or Magmatic" /> Significant crustal thickening occurs in terrestrial [[orogenic belts]] either through [[obduction]] or [[Subsidence crater|isostatic subsidence]] as the mountain grows in height.<ref name="Tectonic or Magmatic" /> Based on the model and the information pertinent to understanding the tectonic environment surrounding the patera, [[anatexis|crustal anatexis]] is a variable model for the origin of [[magmatism]] at Cleopatra Patera.<ref name="Tectonic or Magmatic" /> This process could be associated with other high mountain belts on Venus and with melting of pre-existing rock in the Himalayan granites.<ref name="Tectonic or Magmatic" /> This results in the melting of the lower levels of the thickened crust and potential magmatic activity, volcanism, and [[caldera]] formation at the surface.<ref name="Tectonic or Magmatic" />
Prior to improved satellite imagery from the [[Magellan (spacecraft)|Magellan]] mission, the topography of Venus was interpreted from lower quality images received from [[radio telescopes]] and [[altimetry|altimetric]] data.<ref name="Tectonic or Magmatic" /> This data allowed for a misinterpretation of the crater; however, it is important to understand what was seen geometrically to explain why certain hypotheses withstood many years.<ref name="Volcanic or Impact?" /> It was found that the topographic elevation on Maxwell Montes resulted from a combination of [[Compression fracture|horizontal compression]] and vertical [[crustal thickening]], which in combination allowed for the [[Crust (geology)|lower crust]] to be partially melted, so long as the crustal thickness exceeds 40&nbsp;km.<ref name="Tectonic or Magmatic" /> Significant crustal thickening occurs in terrestrial [[orogenic belts]] either through [[obduction]] or [[Subsidence crater|isostatic subsidence]] as the mountain grows in height.<ref name="Tectonic or Magmatic" /> Based on the model and the information pertinent to understanding the tectonic environment surrounding the patera, [[anatexis|crustal anatexis]] is a variable model for the origin of [[magmatism]] at Cleopatra Patera.<ref name="Tectonic or Magmatic" /> This process could be associated with other high mountain belts on Venus and with melting of pre-existing rock in the Himalayan granites.<ref name="Tectonic or Magmatic" /> This results in the melting of the lower levels of the thickened crust and potential magmatic activity, volcanism, and [[caldera]] formation at the surface.<ref name="Tectonic or Magmatic" />


==Volcanic evidence==
===Volcanic evidence===
The following evidence from Scraber et al.<ref name="Venera 15/16" /> was the leading explanation for a volcanic origin for twelve years until Magellan imagery was returned in the early 1990s.<ref name="Venusian Impact Craters" /><ref name="Impact craters on Venus, Earth, and other planets" /><ref name="Ring Impact Craters on Venus" /><ref name="Chapter 7: Venus" />
The following evidence from Scraber et al.<ref name="Venera 15/16" /> was the leading explanation for a volcanic origin for twelve years until Magellan imagery was returned in the early 1990s.<ref name="Venusian Impact Craters" /><ref name="Impact craters on Venus, Earth, and other planets" /><ref name="Ring Impact Craters on Venus" /><ref name="Chapter 7: Venus" />
# a volcanic origin of Cleopatra patera included its association with plains forming deposit sloping away from the crater in a lava flow<ref name="Happy Solution" /><ref name="Venera 15/16" />
# a volcanic origin of Cleopatra patera included its association with plains forming deposit sloping away from the crater in a lava flow<ref name="Happy Solution" /><ref name="Venera 15/16" />
Line 26: Line 32:
# the large depth to diameter ratio<ref name="Venusian Impact Craters" /><ref name="Happy Solution" /><ref name="Venera 15/16" />
# the large depth to diameter ratio<ref name="Venusian Impact Craters" /><ref name="Happy Solution" /><ref name="Venera 15/16" />
# and its situation in a regional tectonic environment<ref name="Volcanic or Impact?" /><ref name="Happy Solution" /><ref name="Venera 15/16" />
# and its situation in a regional tectonic environment<ref name="Volcanic or Impact?" /><ref name="Happy Solution" /><ref name="Venera 15/16" />

[[File:Cleopatra Ring Structure Interpretation.png|thumb|300px|left|Volcanotectonic interpretation of ring structures of Cleopatra Patera as interpreted from Peterfreund et al.]]
[[File:Cleopatra Ring Structure Interpretation.png|thumb|300px|left|Volcanotectonic interpretation of ring structures of Cleopatra Patera as interpreted from Peterfreund et al.]]




The best comparison to Cleopatra is the [[Alba Patera]] on Mars and Cleopatera’s ring structure was intensely interpreted to link it to a volcanic origin.<ref name="Volcanic or Impact?" /><ref name="Venera 15/16" /> Peterfreund et al. and Scraber et al. described their interpretation of the rings as follows:
The best comparison to Cleopatra is the [[Alba Patera]] on Mars and Cleopatera’s ring structure was intensely interpreted to link it to a volcanic origin.<ref name="Volcanic or Impact?" /><ref name="Venera 15/16" /> Peterfreund et al. and Scraber et al. described their interpretation of the rings as follows:
#Alba patera has a caldera of similar size to Ring B, interpreted image of rings to the right, and is surrounded by structural patterns produced by tectonic deformation (refer to previous image).<ref name="Volcanic or Impact?" /><ref name="Venera 15/16" />
#Alba patera has a caldera of similar size to Ring B, interpreted image of rings to the right, and is surrounded by structural patterns produced by tectonic deformation (refer to previous image).<ref name="Volcanic or Impact?" /><ref name="Venera 15/16" />
Line 34: Line 45:
#Ring D has a tectonic fracture that was involved in deformation.<ref name="Volcanic or Impact?" />
#Ring D has a tectonic fracture that was involved in deformation.<ref name="Volcanic or Impact?" />


==Crater impact model==
Most large impact craters do not have a central peak, yet have sharp rims bordered by asymmetrical radar bright [[ejecta blanket]]s, have multiple rims, are surrounded and partially filled by subsequent lava which creates a reduced apparent depth, have dark crater floors, and buries some ejecta.<ref name="Venusian Craters " /> By analyzing Magellan images, Cleopatra patera’s was found to be distorted in shape in that its noncircular inner ring is off center, but also that the outflow channel of lava moves from within the crater and reaches the top of the crater rim.<ref name="Ring Impact Craters on Venus" /> The interiors are radar dark and smooth in comparison to the surrounding plains.<ref name="Ring Impact Craters on Venus" /> From the image of Plate P-11 from Venera 15 and 16 shows that Cleopatra patera that was originally interpreted as a large caldera but has now been interpreted as a multi-ringed impact crater with a central peak.<ref name="HIGH-RESOLUTION RADAR IMAGES OF VENUS" /> Using photogeologic analysis, the floor of the crater has a shallow central depression resulting from [[subsidence]] of uplifted [[Mantle (geology)|mantle]] material from below due to "[[viscous]] relaxation".<ref name="Geology and Morphometry of Large Impact Craters of Venus">{{cite journal | title=Geology and Morphometry of Large Impact Craters of Venus | author=Basilevsky, A.T. et al | journal=Lunar and Planetary Science Conference | year=1994 | volume=XXV | pages=67–68}}</ref> This was found in Venusian craters larger than 70&nbsp;km in diameter by using altimetry data which shows surfaces with different elevations from the Magellan mission.<ref name="Geology and Morphometry of Large Impact Craters of Venus" />



==Patera geologic description==

Cleopatra patera has features in that of a double ring impact crater. The crater rim is scalloped and the center of the crater is steeply slanted down to a smooth dark crater floor.<ref name="Volcanic or Impact?" /><ref name="Happy Solution" /> A central peak is found in the center of the crater floor and outside the inner crater is masses of "coarse hummocky terrain." <ref name="Happy Solution" /> The plains surrounding the crater is smooth and bright, but there are some dark deposits around the topographic depressions just north of the crater.<ref name="Volcanic or Impact?" /><ref name="Happy Solution" /><ref name="Ring Impact Craters on Venus" /> These dark deposits are interpreted to be "[[Impact crater|shock-melt material]]" equivalent to ejecta blanket material; however, the dark deposits to the south are "ridge slopes."<ref name="Happy Solution" /> The outflow of material to the right of the crater is [[lava flows]] which have spilled from the bowl shape of the crater due to the impact hitting the steep side of Maxwell Montes, occurring at impact.<ref name="Happy Solution" /> When the [[magma chamber]] at the floor of Cleopatra erupted, subsidence occurred explaining the large depth of the crater.<ref name="Happy Solution" /><ref name="Geology and Morphometry of Large Impact Craters of Venus" />



==See also==
==See also==

Revision as of 17:05, 18 April 2014

Template:Infobox feature on Venus

Zoomed in view extrapolated from Magellan imagery of Cleopatra patera, eastern flank of Maxwell Montes on Ishtar Terra, Venus.

Cleopatra Patera is a nearly circular double ring crater on Venus, 2–3 km deep and 105 km in diameter.[1][2][3][4][5][6][7] A patera is geologic feature defined as a crater formed by impact or volcanic origin. Cleopatra patera is unusual in that its origin was debated for twelve years.[4][2] A volcanic origin initially was supported due to non-impact geologic aspects, such as having a low rim, a surrounding plains-forming unit, and a non-concentric nature of its inner basin, as well as its proximity to Maxwell Montes.[4][6][8] However, as more recent missions to Venus improved in the clarity of topographic imagery from Arecibo radio telescope and Venera 15/16 space crafts, the structures seen in the crater has cleared the scientific controversy and has been since identified as an impact crater.[1][4][7][9][10]

Crater impact model

Most large impact craters do not have a central peak, yet have sharp rims bordered by asymmetrical radar bright ejecta blankets, have multiple rims, are surrounded and partially filled by subsequent lava which creates a reduced apparent depth, have dark crater floors, and buries some ejecta.[10] By analyzing Magellan images, Cleopatra patera’s was found to be distorted in shape in that its noncircular inner ring is off center, but also that the outflow channel of lava moves from within the crater and reaches the top of the crater rim.[6] The interiors are radar dark and smooth in comparison to the surrounding plains.[6] From the image of Plate P-11 from Venera 15 and 16 shows that Cleopatra patera that was originally interpreted as a large caldera but has now been interpreted as a multi-ringed impact crater with a central peak.[9] Using photogeologic analysis, the floor of the crater has a shallow central depression resulting from subsidence of uplifted mantle material from below due to "viscous relaxation".[11] This was found in Venusian craters larger than 70 km in diameter by using altimetry data which shows surfaces with different elevations from the Magellan mission.[11]

Patera geologic description

Cleopatra patera has features in that of a double ring impact crater. The crater rim is scalloped and the center of the crater is steeply slanted down to a smooth dark crater floor.[2][4] A central peak is found in the center of the crater floor and outside the inner crater is masses of "coarse hummocky terrain." [4] The plains surrounding the crater is smooth and bright, but there are some dark deposits around the topographic depressions just north of the crater.[2][4][6] These dark deposits are interpreted to be "shock-melt material" equivalent to ejecta blanket material; however, the dark deposits to the south are "ridge slopes."[4] The outflow of material to the right of the crater is lava flows which have spilled from the bowl shape of the crater due to the impact hitting the steep side of Maxwell Montes, occurring at impact.[4] When the magma chamber at the floor of Cleopatra erupted, subsidence occurred explaining the large depth of the crater.[4][11]

Original volcanic model

Caldera formation process

Prior to improved satellite imagery from the Magellan mission, the topography of Venus was interpreted from lower quality images received from radio telescopes and altimetric data.[3] This data allowed for a misinterpretation of the crater; however, it is important to understand what was seen geometrically to explain why certain hypotheses withstood many years.[2] It was found that the topographic elevation on Maxwell Montes resulted from a combination of horizontal compression and vertical crustal thickening, which in combination allowed for the lower crust to be partially melted, so long as the crustal thickness exceeds 40 km.[3] Significant crustal thickening occurs in terrestrial orogenic belts either through obduction or isostatic subsidence as the mountain grows in height.[3] Based on the model and the information pertinent to understanding the tectonic environment surrounding the patera, crustal anatexis is a variable model for the origin of magmatism at Cleopatra Patera.[3] This process could be associated with other high mountain belts on Venus and with melting of pre-existing rock in the Himalayan granites.[3] This results in the melting of the lower levels of the thickened crust and potential magmatic activity, volcanism, and caldera formation at the surface.[3]

Volcanic evidence

The following evidence from Scraber et al.[8] was the leading explanation for a volcanic origin for twelve years until Magellan imagery was returned in the early 1990s.[1][5][6][7]

  1. a volcanic origin of Cleopatra patera included its association with plains forming deposit sloping away from the crater in a lava flow[4][8]
  2. the depth and steepness of the walls of the crater interpreted as multiple calderas[4][8]
  3. the elongation of the outer rim deposits following along the same path as the tectonic features of the area[3][4][8]
  4. the absence of a raised highly backscattered rim deposit seen in impact craters[3][4][8]
  5. the large depth to diameter ratio[1][4][8]
  6. and its situation in a regional tectonic environment[2][4][8]
Volcanotectonic interpretation of ring structures of Cleopatra Patera as interpreted from Peterfreund et al.



The best comparison to Cleopatra is the Alba Patera on Mars and Cleopatera’s ring structure was intensely interpreted to link it to a volcanic origin.[2][8] Peterfreund et al. and Scraber et al. described their interpretation of the rings as follows:

  1. Alba patera has a caldera of similar size to Ring B, interpreted image of rings to the right, and is surrounded by structural patterns produced by tectonic deformation (refer to previous image).[2][8]
  2. Cleopatra shares commonalities with impact craters on Venus because of it radially smooth interior and rough exterior.[2][8] However, the asymmetry of ring A challenges an impact hypothesis.[2][8]
  3. Ring C and D represents structural areas associated with the initial crater[2]
  4. The area within C is related to material ejected from a volcano or has been heavily fractured and deformed much different than the surrounding terrain.[2]
  5. Ring D has a tectonic fracture that was involved in deformation.[2]




See also

References

  1. ^ a b c d Hamilton, Calvin (1993). "Venusian Impact Craters". Soler Views. Retrieved 3 April 2014.
  2. ^ a b c d e f g h i j k l m Peterfreud, A.R. (1984). Head, J.W. (ed.). Cleopatra Patera, A Circular Structure in Maxwell Montes, Venus; Volcanic or Impact?. Lunar and Planetary Science. Brown University. pp. 641–642. {{cite conference}}: |access-date= requires |url= (help) Cite error: The named reference "Volcanic or Impact?" was defined multiple times with different content (see the help page).
  3. ^ a b c d e f g h i Nikishin, A.M. (1988). "Tectonic and Magmatic Models for the Origin of Cleopatra Patera". Lunar and Planetary Science Conference: 860–861.
  4. ^ a b c d e f g h i j k l m n o p Basilevsky, A.T.; et al. (1991). "Cleopatra Crater on Venus: Happy Solution of the Volcanic vs Impact Controversy". Lunar and Planetary Science Conference. XXII (22): 59–60. {{cite journal}}: Explicit use of et al. in: |author= (help)
  5. ^ a b Athena Publications (2001). "Impact craters on Venus, Earth, and other planets". Athena Review. Retrieved 3 April 2014.
  6. ^ a b c d e f Alexopoulos, Jim and William McKinnon (1993). "RINGED IMPACT CRATERS ON VENUS: AN ANALYSIS FROM MAGELLAN IMAGES". International Colloquium on Venus. pp. 2–4. Retrieved 3 April 2014.
  7. ^ a b c Christiansen, Eric (1995). "Exploring the Planets". Prentice Hall. Retrieved 3 April 2014.
  8. ^ a b c d e f g h i j k l Schaber, Gerald (1987). "Cleopatra Patera on Venus: Venera 15/16 Evidence for a Volcanic Origin". Geophysical Research Letters. 14 (1): 41–44. {{cite journal}}: Unknown parameter |month= ignored (help)
  9. ^ a b Kempler, Steven (2009). "HIGH-RESOLUTION RADAR IMAGES OF VENUS". NASA. Retrieved 3 April 2014.
  10. ^ a b Vita-Finzi, C; et al. (2004). "Venusian Craters and the Origin of Coronae". Lunar and Planetary Science. Retrieved 4 April 2014. {{cite web}}: Explicit use of et al. in: |author= (help)
  11. ^ a b c Basilevsky, A.T.; et al. (1994). "Geology and Morphometry of Large Impact Craters of Venus". Lunar and Planetary Science Conference. XXV: 67–68. {{cite journal}}: Explicit use of et al. in: |author= (help)
Retrieved from "https://en.wikipedia.org/w/index.php?title=Cleopatra_Patera&oldid=604762571"