fbpx
Wikipedia

Central Atlantic magmatic province

October 29, 2023

The Central Atlantic magmatic province (CAMP) is the Earth's largest continental large igneous province, covering an area of roughly 11 million km2. It is composed mainly of basalt that formed before Pangaea broke up in the Mesozoic Era, near the end of the Triassic and the beginning of the Jurassic periods. The subsequent breakup of Pangaea created the Atlantic Ocean, but the massive igneous upwelling provided a legacy of basaltic dikes, sills, and lavas now spread over a vast area around the present central North Atlantic Ocean, including large deposits in northwest Africa, southwest Europe, as well as northeast South America and southeast North America (found as continental tholeiitic basalts in subaerial flows and intrusive bodies). The name and CAMP acronym were proposed by Andrea Marzoli (Marzoli et al. 1999) and adopted at a symposium held at the 1999 Spring Meeting of the American Geophysical Union.

Central Atlantic magmatic province
CAMP
Large igneous province
Location of large residual elements of the CAMP
LocationCentral North Atlantic Ocean, northwest Africa, southwest Europe, northeast South & southeast North America
Offshore water bodiesAtlantic Ocean
Agelatest Triassic-Early Jurassic
OrogenyBreak-up of Pangea
Area
 • Total11,000,000 km2 (1.2×1014 sq ft)
Dimensions
 • Length5,000 km (3,100 mi)
 • Width2,500 km (1,600 mi)
Last eruptionHettangian

The CAMP volcanic eruptions occurred about 201 million years ago and split into four pulses lasting for over ~600,000 years. The resulting large igneous province is, in area covered, the most extensive on Earth. The volume of magma flow of between two and six million cubic kilometres makes it one of the most voluminous as well.[1][2]

This geologic event is associated with the Triassic–Jurassic extinction event.[3][1]

Connected magma flows edit

Although some connections among these basalts had long been recognized, in 1988 they were linked as constituting a single major flood basalt province.[4] The basaltic sills of similar age (near 200 Ma, or earliest Jurassic) and composition (intermediate-Ti quartz tholeiite) which occur across the vast Amazon River basin of Brazil were linked to the province in 1999.[5] Remnants of CAMP have been identified on four continents (Africa, Europe, North America and South America) and consist of tholeiitic basalts formed during the opening of the Atlantic Ocean basin during the breakup of the Pangean supercontinent.[1]

Geographical extent edit

The province has been described as extending within Pangaea from present-day central Brazil northeastward about 5,000 kilometres (3,100 mi) across western Africa, Iberia, and northwestern France, and from the interior of western Africa westward for 2,500 kilometres (1,600 mi) through eastern and southern North America.[6] If not the largest province by volume, the CAMP certainly encompasses the greatest area known, roughly 11,000,000 square kilometres (4,200,000 sq mi), of any continental large igneous province.

Nearly all CAMP rocks are tholeiitic in composition, with widely separated areas where basalt flows are preserved, as well as large groups of diabase (dolerite) sills or sheets, small lopoliths, and dikes throughout the province. Dikes occur in very large individual swarms with particular compositions and orientations. CAMP activity is apparently related to the rifting and breakup of Pangaea during the Late Triassic through Early Jurassic periods, and the enormous province size, varieties of basalt, and brief time span of CAMP magmatism invite speculation about mantle processes that could produce such a magmatic event as well as rift a supercontinent.[7][6]

Connection with the Triassic-Jurassic boundary and the associated mass extinction event edit

In 2013 the CAMP's connection to the end-Triassic extinction, with major extinctions that enabled dinosaur domination of land, became more firmly established. Until 2013, the uncertainties in the geochronologic dates had been too coarse to confirm that the volcanic eruptions were correlated with major climate changes. The work by Blackburn et al. demonstrated a tight synchroneity between the earliest volcanism and extinction of large populations using zircon uranium-lead (U-Pb) dating. They further demonstrated that the magmatic eruptions as well as the accompanying atmospheric changes were split into four pulses lasting for over ~600,000 years.[1]

Before that integration, two hypotheses were in debate. One hypothesis was based especially on studies on Triassic-Jurassic basins from Morocco where CAMP lava flows are outcropping,[8] whereas the other was based on end-Triassic extinction data from eastern North American basins and lava flows showing an extremely large turnover in fossil pollen, spores (sporomorphs), and vertebrates,[9] respectively.

Morocco edit

 
A basaltic lava flow section from the Middle Atlas, Morocco

The thickest lava flow sequences of the African CAMP are in Morocco, where there are basaltic lava piles more than 300 metres thick. The most-studied area is Central High Atlas, where the best preserved and most complete basaltic lava piles are exposed. According to geochemical, petrographic and isotopic data four distinct tholeiitic basaltic units were recognized and can be placed throughout the Central High Atlas: Lower, Intermediate, Upper and Recurrent basalts.

The Lower and Intermediate units are constituted by basaltic andesites, whereas the Upper and Recurrent units have basaltic composition. From Lower to Recurrent unit, we observe:

  • a progressive decrease of eruption rate (the Lower and the Intermediate units represent over 80% of preserved lava volume);
  • a trend going from intersertal to porphyritic texture;
  • a progressive depletion of incompatible element contents in the basalts, possibly linked to a progressive depletion of their mantle source.

Isotopic analyses edit

Ages were determined by 40Ar/39Ar analysis on plagioclase.[10][11][12] These data show indistinguishable ages (199.5±0.5 Ma) from Lower to Upper lava flows, from central to northern Morocco. Therefore, CAMP was an intense, short magmatic event. Basalts of the Recurrent unit are slightly younger (mean age: 197±1 Ma) and represent a late event. Consistently, the Upper and Recurrent basalts are separated by a sedimentary layer that locally reaches a thickness of circa 80 m.

Magnetostratigraphy edit

According to magnetostratigraphic data, the Moroccan CAMP events were divided into five groups, differing in paleomagnetic orientations (declination and inclination).[10] Each group is composed by a smaller number of lava flows (i.e., a lower volume) than the preceding one. These data suggest that they were created by five short magma pulses and eruption events, each one possibly <400 (?) years long. All lava flow sequences are characterized by normal polarity, except for a brief paleomagnetic reversal yielded by one lava flow and by a localized interlayered limestone in two distinct section of the High Atlas CAMP.

Palynological analyses edit

Palynological data from sedimentary layers samples at the base of four lava flow sequences constrain the onset of the CAMP, since there is no evidence of depositional hiatus or tectonic deformation at the bottom of the lava flow piles.[12] The palynological assemblage observed in these basal layers is typical of Late Triassic age, similar to that of the uppermost Triassic sedimentary rocks of eastern North America. Samples from interlayered limestone in lava flows provided unreliable palynological data. One limestone bed from the top to the central High Atlas upper basalts yielded a Late Triassic palynological assemblage. However, the observed sporomorphs in this sample are rare and poorly preserved.

Conclusions edit

All of these data indicate that the basaltic lava flows of the Central Atlantic magmatic province in Morocco were erupted at c. 200 Ma and spanned the Tr-J boundary. Thus, it is very possible that there is a connection between this magmatic event and the Tr-J boundary climatic and biotic crisis that led to the mass-extinction.

Eastern North America edit

 
Basal contact of the North Mountain section of Fundy basin, Nova Scotia, Canada

The North American portion of the CAMP lava flows crop out in various sections in the basins of Newark, Culpeper, Hartford, Deerfield, i.e. the Newark Supergroup in New England (USA), and in the Fundy Basin in Nova Scotia (Canada). The CAMP is here constituted by rare olivine- and common quartz-normative basalts showing a great lateral extension and a maximum thickness up to 1 km. The basaltic flows occur on top of continental fluvial and lacustrine sedimentary units of Triassic age. 40Ar/39Ar data (on plagioclase) indicate for these basaltic units an absolute age of 198-200 Ma[13] bringing this magmatic event undoubtedly close to the Triassic-Jurassic (Tr-J) boundary. Thus it is necessary to determine whether it straddles the boundary or not: if not, then the CAMP could not be a cause of the Late Triassic extinction event. For example, according to Whiteside et al. (2007) there are palynological, geochemical, and magnetostratigraphic evidences that the CAMP postdates the Tr-J boundary.

Magnetostratigraphy edit

In the Newark Basin, a magnetic reversal (E23r) is observed just below the oldest basalts and more or less in the same position as a palynologic turnover, interpreted as the Tr-J boundary. In Morocco, two reversals have been detected in two lava flow sequences. Two distinct correlations between the Moroccan and the Newark magnetostratigraphy have been proposed. Marzoli et al. (2004) suggest that the Tr-J boundary is located above the lower reverse polarity level which is positioned more or less at the base of the Intermediate basalt unit of Morocco. These two levels can be correlated with chron E23r of the Newark Basin, therefore the North American CAMP Basalts postdate the Tr–J boundary whereas part of the Moroccan CAMP was erupted within the Triassic. Contrarily, Whiteside et al. (2007) propose that these two levels could be earliest Jurassic intervals of reverse polarity not sampled in the Newark Basin Sequence (many more lava flows are present in the Moroccan Succession than in the Newark Basin), but observed in Early Jurassic sedimentary sequences of the Paris Basin of France. Reverse polarity intervals in America could be present within North Mountain (Fundy basin, Nova Scotia) which are poorly sampled even if previous magnetostratigraphy analysis in this sequence showed only normal polarity, or in the Scots Bay Member of the Fundy basin which have never been sampled. There is only one outcrop in the CAMP of America where reverse polarity is observable: a CAMP–related (about 200 Ma) dike in North Carolina. Whiteside et al. (2007) suggest that reverse polarity intervals in this dike could be of post Triassic age and correlated with the same events in Morocco.

Palynological analyses edit

The Tr-J boundary is not officially defined, but most workers recognise it in continental strata by the last appearance of index taxa such as Ovalipollis ovalis, Vallasporites ignatii and Patinasporites densus or, in marine sections, by the first appearance of the ammonite Psiloceras planorbis. In the Newark basin the palynological turnover event (hence the Tr-J boundary mass extinction) occurs below the oldest CAMP lava flows. The same can be said for the Fundy, Hartford and Deerfield Basins. In the investigated Moroccan CAMP sections (Central High Atlas Basin), sedimentary layers sampled immediately below the oldest basaltic lava flows, apparently contain Triassic taxa (e.g., P. densus), and were thus defined as Triassic in age as at least the lowest lava flows .[12] Still, a different interpretation is suggested by Whiteside et al. (2007): the sampled sedimentary strata are quite deformed and this can mean that some sedimentary units could be lacking (eroded or structurally omitted). With respect to the Triassic pollens found in some sedimentary units above the Upper Unit basalts, they could have been reworked, so they don’t represent a completely reliable constraint.

Geochemical analyses edit

CAMP lava flows of North America can be geochemically separated in three units: the older ones are classified as high titanium quartz normative (HTQ) basalts (TiO2 = 1.0-1.3 wt%); these are followed by lava flows classified as low titanium quartz normative (LTQ) basalts (TiO2 = ca. 0.8-1.3 wt%); and then by the youngest lava flow unit classified as high titanium iron quartz normative (HTIQ) basalts (TiO2 = 1.4-1.6 wt%). According to Whiteside et al. (2007), geochemical analyses based upon titanium, magnesium and silicon contents show a certain correlation between the lower North American lava flows and the Lower Unit of the Moroccan CAMP, thus reinforcing the conclusion that the Moroccan basalts postdate the Tr-J boundary.

Therefore, according to these data, CAMP basalts shouldn’t be included among the direct causes of the Tr-J mass extinction.

References edit

  1. ^ a b c d Blackburn et al. (2013).
  2. ^ Capriolo et al. (2022).
  3. ^ Whalen et al. (2015).
  4. ^ Rampino & Stothers (1988).
  5. ^ Marzoli et al. (1999).
  6. ^ a b McHone (2000).
  7. ^ Wilson (1997).
  8. ^ e.g., Marzoli et al. (2004)
  9. ^ Whiteside et al. (2007).
  10. ^ a b Knight et al. (2004).
  11. ^ Verati et al. (2007).
  12. ^ a b c Marzoli et al. (2004).
  13. ^ Hames et al. (2003).

Bibliography edit

  • Blackburn, Terrence J.; Olsen, Paul E.; Bowring, Samuel A.; McLean, Noah M.; Kent, Dennis V.; Puffer, John; McHone, Greg; Rasbury, Troy; Et-Touhami7, Mohammed (2013). "Zircon U-Pb Geochronology Links the End-Triassic Extinction with the Central Atlantic Magmatic Province". Science. 340 (6135): 941–945. Bibcode:2013Sci...340..941B. CiteSeerX 10.1.1.1019.4042. doi:10.1126/science.1234204. PMID 23519213. S2CID 15895416.
  • Capriolo, Manfredo; Mills, Benjamin J. W.; Newton, Robert J.; Corso, Jacobo Dal; Dunhill, Alexander M.; Wignall, Paul B.; Marzoli, Andrea (February 2022). "Anthropogenic-scale CO2 degassing from the Central Atlantic Magmatic Province as a driver of the end-Triassic mass extinction". Global and Planetary Change. 209: 103731. Bibcode:2022GPC...20903731C. doi:10.1016/j.gloplacha.2021.103731. S2CID 245530815.
  • Fowell, S.J.; Traverse, A. (1995). "Palynology and age of the upper Blomidon Formation, Fundy Basin, Nova Scotia". Review of Palaeobotany and Palynology. 86 (3–4): 211–233. Bibcode:1995RPaPa..86..211F. doi:10.1016/0034-6667(94)00147-C.
  • Hames, W.E.; McHone, J.G.; Renne, P.; Ruppel, C., eds. (2003). The Central Atlantic Magmatic Province: Insights from Fragments of Pangea. Vol. 136. American Geophysical Union Monograph. p. 267. ISBN 978-0-87590-995-0.
  • Knight, K.B.; Nomade, S.; Renne, P.R.; Marzoli, A.; Betrand, H.; Youbi, N. (2004). "The Central Atlantic magmatic province at the Triassic–Jurassic boundary: paleomagnetic and 40Ar/30Ar evidence from Morocco for brief, episodic volcanism". Earth and Planetary Science Letters. 228 (1–2): 143–160. Bibcode:2004E&PSL.228..143K. doi:10.1016/j.epsl.2004.09.022.
  • McHone, J.G. (2000). "Non-plume magmatism and rifting during the opening of the Central Atlantic Ocean". Tectonophysics. 316 (3–4): 287–296. Bibcode:2000Tectp.316..287M. doi:10.1016/S0040-1951(99)00260-7.
  • McHone, J.G. (2003). "Volatile emissions of Central Atlantic Magmatic Province basalts: Mass assumptions and environmental consequences" (PDF). In Hames, W.E.; Mchone, J.G.; Renne, P.; et al. (eds.). The Central Atlantic Magmatic Province: Insights from Fragments of Pangea. pp. 241–254. Bibcode:2003GMS...136..241M. doi:10.1029/136GM013. ISBN 978-0-87590-995-0. Retrieved 8 August 2015. {{cite book}}: |journal= ignored (help)
  • Marzoli, A.; Renne, P.R.; Piccirillo, E.M.; Ernesto, M.; Bellieni, G.; De Min, A. (1999). "Extensive 200 million-year-old continental flood basalts of the central Atlantic magmatic province". Science. 284 (5414): 616–618. Bibcode:1999Sci...284..616M. doi:10.1126/science.284.5414.616. PMID 10213679.
  • Marzoli, A.; Bertrand, H.; Knight, K.B.; Cirilli, S.; N. Buratti; C. Vérati; S. Nomade; P.R. Renne; N. Youbi; R. Martini; K. Allenbach; R. Neuwerth; C. Rapaille; L. Zaninetti; G. Bellieni (2004). (PDF). Geology. 32–11 (11): 973–976. Bibcode:2004Geo....32..973M. doi:10.1130/G20652.1. Archived from the original (PDF) on 2011-06-13.
  • Rampino, Michael R.; Stothers, Richard B. (5 Aug 1988). "Flood Basalt Volcanism During the Past 250 Million Years". Science. 241 (4866): 663–668. Bibcode:1988Sci...241..663R. doi:10.1126/science.241.4866.663. PMID 17839077. S2CID 33327812.
  • Veratia, Chrystèle; Rapaille, Cédric; Férauda, Gilbert; Marzoli, Andrea; Bertrand, Hervé; Youbi, Nasrrddine (9 February 2007). "40Ar/39Ar ages and duration of the Central Atlantic Magmatic Province volcanism in Morocco and Portugal and its relation to the Triassic–Jurassic boundary". Palaeogeography, Palaeoclimatology, Palaeoecology. Triassic-Jurassic Boundary events: problems, progress, possibilities. 244 (1–4): 308–325. Bibcode:2007PPP...244..308V. doi:10.1016/j.palaeo.2006.06.033.
  • Whiteside, J.H.; Olsen, P.E.; Kent, D.V.; Fowell, S.J.; Et-Touhami, M. (2007). "Synchrony between the Central Atlantic magmatic province and the Triassic-Jurassic mass-extinction event?". Palaeo. 244 (1–4): 345–367. Bibcode:2007PPP...244..345W. doi:10.1016/j.palaeo.2006.06.035.
  • Whalen, Lisa; Gazel, Esteban; Vidito, Christopher; Puffer, John; Bizinis, Michael; Henika, William; Caddick, Mark J. (3 September 2015). "Supercontinental inheritance and its influence on supercontinental breakup: The Central Atlantic Magmatic Province and the breakup of Pangea". Paleoceanography and Paleoclimatology. 16 (10): 3532–3554. Bibcode:2015GGG....16.3532W. doi:10.1002/2015GC005885. S2CID 129223849.
  • Wilson, M. (1997). "Thermal evolution of the Central Atlantic passive margins: Continental break-up above a Mesozoic super-plume". Journal of the Geological Society. 154 (3): 491–495. Bibcode:1997JGSoc.154..491W. doi:10.1144/gsjgs.154.3.0491. S2CID 128997332.

External links edit

October 29, 2023
central, atlantic, magmatic, province, this, scientific, article, needs, additional, citations, secondary, tertiary, sourcessuch, review, articles, monographs, textbooks, please, such, references, provide, context, establish, relevance, primary, research, arti. This scientific article needs additional citations to secondary or tertiary sourcessuch as review articles monographs or textbooks Please add such references to provide context and establish the relevance of any primary research articles cited Unsourced or poorly sourced material may be challenged and removed April 2023 Learn how and when to remove this template message The Central Atlantic magmatic province CAMP is the Earth s largest continental large igneous province covering an area of roughly 11 million km2 It is composed mainly of basalt that formed before Pangaea broke up in the Mesozoic Era near the end of the Triassic and the beginning of the Jurassic periods The subsequent breakup of Pangaea created the Atlantic Ocean but the massive igneous upwelling provided a legacy of basaltic dikes sills and lavas now spread over a vast area around the present central North Atlantic Ocean including large deposits in northwest Africa southwest Europe as well as northeast South America and southeast North America found as continental tholeiitic basalts in subaerial flows and intrusive bodies The name and CAMP acronym were proposed by Andrea Marzoli Marzoli et al 1999 and adopted at a symposium held at the 1999 Spring Meeting of the American Geophysical Union Central Atlantic magmatic province CAMPLarge igneous provinceLocation of large residual elements of the CAMPLocationCentral North Atlantic Ocean northwest Africa southwest Europe northeast South amp southeast North AmericaOffshore water bodiesAtlantic OceanAgelatest Triassic Early JurassicOrogenyBreak up of PangeaArea Total11 000 000 km2 1 2 1014 sq ft Dimensions Length5 000 km 3 100 mi Width2 500 km 1 600 mi Last eruptionHettangianThe CAMP volcanic eruptions occurred about 201 million years ago and split into four pulses lasting for over 600 000 years The resulting large igneous province is in area covered the most extensive on Earth The volume of magma flow of between two and six million cubic kilometres makes it one of the most voluminous as well 1 2 This geologic event is associated with the Triassic Jurassic extinction event 3 1 Contents 1 Connected magma flows 2 Geographical extent 3 Connection with the Triassic Jurassic boundary and the associated mass extinction event 3 1 Morocco 3 1 1 Isotopic analyses 3 1 2 Magnetostratigraphy 3 1 3 Palynological analyses 3 1 4 Conclusions 3 2 Eastern North America 3 2 1 Magnetostratigraphy 3 2 2 Palynological analyses 3 2 3 Geochemical analyses 4 References 4 1 Bibliography 5 External linksConnected magma flows editAlthough some connections among these basalts had long been recognized in 1988 they were linked as constituting a single major flood basalt province 4 The basaltic sills of similar age near 200 Ma or earliest Jurassic and composition intermediate Ti quartz tholeiite which occur across the vast Amazon River basin of Brazil were linked to the province in 1999 5 Remnants of CAMP have been identified on four continents Africa Europe North America and South America and consist of tholeiitic basalts formed during the opening of the Atlantic Ocean basin during the breakup of the Pangean supercontinent 1 Geographical extent editThe province has been described as extending within Pangaea from present day central Brazil northeastward about 5 000 kilometres 3 100 mi across western Africa Iberia and northwestern France and from the interior of western Africa westward for 2 500 kilometres 1 600 mi through eastern and southern North America 6 If not the largest province by volume the CAMP certainly encompasses the greatest area known roughly 11 000 000 square kilometres 4 200 000 sq mi of any continental large igneous province Nearly all CAMP rocks are tholeiitic in composition with widely separated areas where basalt flows are preserved as well as large groups of diabase dolerite sills or sheets small lopoliths and dikes throughout the province Dikes occur in very large individual swarms with particular compositions and orientations CAMP activity is apparently related to the rifting and breakup of Pangaea during the Late Triassic through Early Jurassic periods and the enormous province size varieties of basalt and brief time span of CAMP magmatism invite speculation about mantle processes that could produce such a magmatic event as well as rift a supercontinent 7 6 Connection with the Triassic Jurassic boundary and the associated mass extinction event editIn 2013 the CAMP s connection to the end Triassic extinction with major extinctions that enabled dinosaur domination of land became more firmly established Until 2013 the uncertainties in the geochronologic dates had been too coarse to confirm that the volcanic eruptions were correlated with major climate changes The work by Blackburn et al demonstrated a tight synchroneity between the earliest volcanism and extinction of large populations using zircon uranium lead U Pb dating They further demonstrated that the magmatic eruptions as well as the accompanying atmospheric changes were split into four pulses lasting for over 600 000 years 1 Before that integration two hypotheses were in debate One hypothesis was based especially on studies on Triassic Jurassic basins from Morocco where CAMP lava flows are outcropping 8 whereas the other was based on end Triassic extinction data from eastern North American basins and lava flows showing an extremely large turnover in fossil pollen spores sporomorphs and vertebrates 9 respectively Morocco edit nbsp A basaltic lava flow section from the Middle Atlas MoroccoThe thickest lava flow sequences of the African CAMP are in Morocco where there are basaltic lava piles more than 300 metres thick The most studied area is Central High Atlas where the best preserved and most complete basaltic lava piles are exposed According to geochemical petrographic and isotopic data four distinct tholeiitic basaltic units were recognized and can be placed throughout the Central High Atlas Lower Intermediate Upper and Recurrent basalts The Lower and Intermediate units are constituted by basaltic andesites whereas the Upper and Recurrent units have basaltic composition From Lower to Recurrent unit we observe a progressive decrease of eruption rate the Lower and the Intermediate units represent over 80 of preserved lava volume a trend going from intersertal to porphyritic texture a progressive depletion of incompatible element contents in the basalts possibly linked to a progressive depletion of their mantle source Isotopic analyses edit Ages were determined by 40Ar 39Ar analysis on plagioclase 10 11 12 These data show indistinguishable ages 199 5 0 5 Ma from Lower to Upper lava flows from central to northern Morocco Therefore CAMP was an intense short magmatic event Basalts of the Recurrent unit are slightly younger mean age 197 1 Ma and represent a late event Consistently the Upper and Recurrent basalts are separated by a sedimentary layer that locally reaches a thickness of circa 80 m Magnetostratigraphy edit According to magnetostratigraphic data the Moroccan CAMP events were divided into five groups differing in paleomagnetic orientations declination and inclination 10 Each group is composed by a smaller number of lava flows i e a lower volume than the preceding one These data suggest that they were created by five short magma pulses and eruption events each one possibly lt 400 years long All lava flow sequences are characterized by normal polarity except for a brief paleomagnetic reversal yielded by one lava flow and by a localized interlayered limestone in two distinct section of the High Atlas CAMP Palynological analyses edit Palynological data from sedimentary layers samples at the base of four lava flow sequences constrain the onset of the CAMP since there is no evidence of depositional hiatus or tectonic deformation at the bottom of the lava flow piles 12 The palynological assemblage observed in these basal layers is typical of Late Triassic age similar to that of the uppermost Triassic sedimentary rocks of eastern North America Samples from interlayered limestone in lava flows provided unreliable palynological data One limestone bed from the top to the central High Atlas upper basalts yielded a Late Triassic palynological assemblage However the observed sporomorphs in this sample are rare and poorly preserved Conclusions edit All of these data indicate that the basaltic lava flows of the Central Atlantic magmatic province in Morocco were erupted at c 200 Ma and spanned the Tr J boundary Thus it is very possible that there is a connection between this magmatic event and the Tr J boundary climatic and biotic crisis that led to the mass extinction Eastern North America edit nbsp Basal contact of the North Mountain section of Fundy basin Nova Scotia CanadaThe North American portion of the CAMP lava flows crop out in various sections in the basins of Newark Culpeper Hartford Deerfield i e the Newark Supergroup in New England USA and in the Fundy Basin in Nova Scotia Canada The CAMP is here constituted by rare olivine and common quartz normative basalts showing a great lateral extension and a maximum thickness up to 1 km The basaltic flows occur on top of continental fluvial and lacustrine sedimentary units of Triassic age 40Ar 39Ar data on plagioclase indicate for these basaltic units an absolute age of 198 200 Ma 13 bringing this magmatic event undoubtedly close to the Triassic Jurassic Tr J boundary Thus it is necessary to determine whether it straddles the boundary or not if not then the CAMP could not be a cause of the Late Triassic extinction event For example according to Whiteside et al 2007 there are palynological geochemical and magnetostratigraphic evidences that the CAMP postdates the Tr J boundary Magnetostratigraphy edit In the Newark Basin a magnetic reversal E23r is observed just below the oldest basalts and more or less in the same position as a palynologic turnover interpreted as the Tr J boundary In Morocco two reversals have been detected in two lava flow sequences Two distinct correlations between the Moroccan and the Newark magnetostratigraphy have been proposed Marzoli et al 2004 suggest that the Tr J boundary is located above the lower reverse polarity level which is positioned more or less at the base of the Intermediate basalt unit of Morocco These two levels can be correlated with chron E23r of the Newark Basin therefore the North American CAMP Basalts postdate the Tr J boundary whereas part of the Moroccan CAMP was erupted within the Triassic Contrarily Whiteside et al 2007 propose that these two levels could be earliest Jurassic intervals of reverse polarity not sampled in the Newark Basin Sequence many more lava flows are present in the Moroccan Succession than in the Newark Basin but observed in Early Jurassic sedimentary sequences of the Paris Basin of France Reverse polarity intervals in America could be present within North Mountain Fundy basin Nova Scotia which are poorly sampled even if previous magnetostratigraphy analysis in this sequence showed only normal polarity or in the Scots Bay Member of the Fundy basin which have never been sampled There is only one outcrop in the CAMP of America where reverse polarity is observable a CAMP related about 200 Ma dike in North Carolina Whiteside et al 2007 suggest that reverse polarity intervals in this dike could be of post Triassic age and correlated with the same events in Morocco Palynological analyses edit The Tr J boundary is not officially defined but most workers recognise it in continental strata by the last appearance of index taxa such as Ovalipollis ovalis Vallasporites ignatii and Patinasporites densus or in marine sections by the first appearance of the ammonite Psiloceras planorbis In the Newark basin the palynological turnover event hence the Tr J boundary mass extinction occurs below the oldest CAMP lava flows The same can be said for the Fundy Hartford and Deerfield Basins In the investigated Moroccan CAMP sections Central High Atlas Basin sedimentary layers sampled immediately below the oldest basaltic lava flows apparently contain Triassic taxa e g P densus and were thus defined as Triassic in age as at least the lowest lava flows 12 Still a different interpretation is suggested by Whiteside et al 2007 the sampled sedimentary strata are quite deformed and this can mean that some sedimentary units could be lacking eroded or structurally omitted With respect to the Triassic pollens found in some sedimentary units above the Upper Unit basalts they could have been reworked so they don t represent a completely reliable constraint Geochemical analyses edit CAMP lava flows of North America can be geochemically separated in three units the older ones are classified as high titanium quartz normative HTQ basalts TiO2 1 0 1 3 wt these are followed by lava flows classified as low titanium quartz normative LTQ basalts TiO2 ca 0 8 1 3 wt and then by the youngest lava flow unit classified as high titanium iron quartz normative HTIQ basalts TiO2 1 4 1 6 wt According to Whiteside et al 2007 geochemical analyses based upon titanium magnesium and silicon contents show a certain correlation between the lower North American lava flows and the Lower Unit of the Moroccan CAMP thus reinforcing the conclusion that the Moroccan basalts postdate the Tr J boundary Therefore according to these data CAMP basalts shouldn t be included among the direct causes of the Tr J mass extinction References edit a b c d Blackburn et al 2013 Capriolo et al 2022 Whalen et al 2015 Rampino amp Stothers 1988 Marzoli et al 1999 a b McHone 2000 Wilson 1997 e g Marzoli et al 2004 Whiteside et al 2007 a b Knight et al 2004 Verati et al 2007 a b c Marzoli et al 2004 Hames et al 2003 Bibliography edit Blackburn Terrence J Olsen Paul E Bowring Samuel A McLean Noah M Kent Dennis V Puffer John McHone Greg Rasbury Troy Et Touhami7 Mohammed 2013 Zircon U Pb Geochronology Links the End Triassic Extinction with the Central Atlantic Magmatic Province Science 340 6135 941 945 Bibcode 2013Sci 340 941B CiteSeerX 10 1 1 1019 4042 doi 10 1126 science 1234204 PMID 23519213 S2CID 15895416 Capriolo Manfredo Mills Benjamin J W Newton Robert J Corso Jacobo Dal Dunhill Alexander M Wignall Paul B Marzoli Andrea February 2022 Anthropogenic scale CO2 degassing from the Central Atlantic Magmatic Province as a driver of the end Triassic mass extinction Global and Planetary Change 209 103731 Bibcode 2022GPC 20903731C doi 10 1016 j gloplacha 2021 103731 S2CID 245530815 Fowell S J Traverse A 1995 Palynology and age of the upper Blomidon Formation Fundy Basin Nova Scotia Review of Palaeobotany and Palynology 86 3 4 211 233 Bibcode 1995RPaPa 86 211F doi 10 1016 0034 6667 94 00147 C Hames W E McHone J G Renne P Ruppel C eds 2003 The Central Atlantic Magmatic Province Insights from Fragments of Pangea Vol 136 American Geophysical Union Monograph p 267 ISBN 978 0 87590 995 0 Knight K B Nomade S Renne P R Marzoli A Betrand H Youbi N 2004 The Central Atlantic magmatic province at the Triassic Jurassic boundary paleomagnetic and 40Ar 30Ar evidence from Morocco for brief episodic volcanism Earth and Planetary Science Letters 228 1 2 143 160 Bibcode 2004E amp PSL 228 143K doi 10 1016 j epsl 2004 09 022 McHone J G 2000 Non plume magmatism and rifting during the opening of the Central Atlantic Ocean Tectonophysics 316 3 4 287 296 Bibcode 2000Tectp 316 287M doi 10 1016 S0040 1951 99 00260 7 McHone J G 2003 Volatile emissions of Central Atlantic Magmatic Province basalts Mass assumptions and environmental consequences PDF In Hames W E Mchone J G Renne P et al eds The Central Atlantic Magmatic Province Insights from Fragments of Pangea pp 241 254 Bibcode 2003GMS 136 241M doi 10 1029 136GM013 ISBN 978 0 87590 995 0 Retrieved 8 August 2015 a href Template Cite book html title Template Cite book cite book a journal ignored help Marzoli A Renne P R Piccirillo E M Ernesto M Bellieni G De Min A 1999 Extensive 200 million year old continental flood basalts of the central Atlantic magmatic province Science 284 5414 616 618 Bibcode 1999Sci 284 616M doi 10 1126 science 284 5414 616 PMID 10213679 Marzoli A Bertrand H Knight K B Cirilli S N Buratti C Verati S Nomade P R Renne N Youbi R Martini K Allenbach R Neuwerth C Rapaille L Zaninetti G Bellieni 2004 Synchrony of the Central Atlantic magmatic province and the Triassic Jurassic boundary climatic and biotic crisis PDF Geology 32 11 11 973 976 Bibcode 2004Geo 32 973M doi 10 1130 G20652 1 Archived from the original PDF on 2011 06 13 Rampino Michael R Stothers Richard B 5 Aug 1988 Flood Basalt Volcanism During the Past 250 Million Years Science 241 4866 663 668 Bibcode 1988Sci 241 663R doi 10 1126 science 241 4866 663 PMID 17839077 S2CID 33327812 Veratia Chrystele Rapaille Cedric Ferauda Gilbert Marzoli Andrea Bertrand Herve Youbi Nasrrddine 9 February 2007 40Ar 39Ar ages and duration of the Central Atlantic Magmatic Province volcanism in Morocco and Portugal and its relation to the Triassic Jurassic boundary Palaeogeography Palaeoclimatology Palaeoecology Triassic Jurassic Boundary events problems progress possibilities 244 1 4 308 325 Bibcode 2007PPP 244 308V doi 10 1016 j palaeo 2006 06 033 Whiteside J H Olsen P E Kent D V Fowell S J Et Touhami M 2007 Synchrony between the Central Atlantic magmatic province and the Triassic Jurassic mass extinction event Palaeo 244 1 4 345 367 Bibcode 2007PPP 244 345W doi 10 1016 j palaeo 2006 06 035 Whalen Lisa Gazel Esteban Vidito Christopher Puffer John Bizinis Michael Henika William Caddick Mark J 3 September 2015 Supercontinental inheritance and its influence on supercontinental breakup The Central Atlantic Magmatic Province and the breakup of Pangea Paleoceanography and Paleoclimatology 16 10 3532 3554 Bibcode 2015GGG 16 3532W doi 10 1002 2015GC005885 S2CID 129223849 Wilson M 1997 Thermal evolution of the Central Atlantic passive margins Continental break up above a Mesozoic super plume Journal of the Geological Society 154 3 491 495 Bibcode 1997JGSoc 154 491W doi 10 1144 gsjgs 154 3 0491 S2CID 128997332 External links editThe CAMP website permanent dead link Map of a small portion of the province Retrieved from https en wikipedia org w index php title Central Atlantic magmatic province amp oldid 1164439217, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.