Earth:Pangean megamonsoon

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The Pangean megamonsoon refers to the theory that the supercontinent Pangea experienced a distinct seasonal reversal of winds, which resulted in extreme transitions between dry and wet periods throughout the year. Pangea was a conglomeration of all the global continental land masses, which lasted from the late Carboniferous to the mid-Jurassic.[1] The megamonsoon intensified as the continents continued to shift toward one another and reached its maximum strength in the Triassic, when the continental surface area of Pangea was at its peak.[2][3] The megamonsoon would have led to immensely arid regions along the interior regions of the continent. Those areas would have been nearly uninhabitable, with extremely hot days and frigid nights. The coasts experienced seasonality, however, and transitioned from rainy weather in the summer to dry conditions during the winter. [3]

Monsoon circulation

Monsoon circulations, defined as a seasonal reversal of winds, exhibit large shifts in precipitation patterns across the impacted region. Monsoons are therefore characterized by two primary seasons: rainy and dry. They are induced by the presence of at least one large land mass and large body of water in close proximity to each other. The most commonly studied present-day monsoon circulation is the East Asian Monsoon.

Discovery

The concept of a Pangean monsoon circulation was first proposed in 1973.[3] The evaporites in the geologic record suggested vast and extensive regions of persistent dry conditions near the Pangean centre, serving as the initial evidence for the theory’s dissemination. The interior of the supercontinent, especially the eastern portion, would have been extremely dry as the hemispheric pressure systems driving the circulation would have diverted nearly all atmospheric moisture away from the region.[3] The later indication of a monsoon-driven climate was acquired via the examination of coal deposits along the exterior portions of the continent. The presence of both features in the geologic record suggested monsoonal circulations.[3]

As the theory of the Pangean megamonsoon began to increase in credibility, paleoclimatologists predicted the climatological impacts of the circulation to ascertain whether observations and models supported the hypothesis. The general consensus listed four primary signs that needed to be present to validate the existence of megamonsoon.[3] Firstly, the lithologic indicators of seasonality should span broad distances along the Pangean coasts. Next, evidence depicting a deviation from zonal flow regimes also needed to be identified. Then, records should indicate that the equatorial regions of Pangea would have been plagued by persistent aridity. Finally, models and geologic observations would need to demonstrate that this circulation peaked during the Triassic.[3]

Monsoon climate on Pangea

In the Northern Hemisphere's summer, when the earth’s axial tilt was directed toward the sun, Laurasia would have received the most direct solar insolation,which would have yielded a broad area of warm, rising air and low surface pressure over the continent. Models have suggested that this seasonal low was positioned at 35° latitude, relatively near the Tethys Ocean.[4] In Gondwana, high pressure would have dominated, as the land would have been receiving less solar radiation, and therefore experiencing cooler temperatures.[5]

The pressure gradient force dictates that air will travel from regions of high to low pressure. That would have driven the atmospheric flow from the Southern Hemisphere toward Laurasia during which it would cross the Tethys Ocean. Water from the Tethys would evaporate into the air mass. Eventually, the air mass would reach the coast of Laurasia and surface convergence resulted in immense amounts of precipitation.[5] Models estimate the globally-averaged precipitation to equal roughly 1000 mm per year, with coastal regions receiving upwards of 8 mm of rain each day during the rainy season.[4] As the atmospheric flow was directed away from the Gondwana high pressure system, surface winds would have diverged and subsidence dominated, producing clear and very dry conditions across the Southern Hemisphere.[4]

Several studies have indicated that the circulation was so intense during the Triassic, it would have been capable of reversing part of the predominantly-easterly global wind flow [3][6][7] and so westerly winds impacted the western coast. That worked to maximize surface convergence and increased seasonality along the western coasts of each continent.[3]

During the Northern Hemisphere winter, when the earth’s tilt was directed away from the sun, the circulation reversed as the area of maximum solar insolation shifted toward the Southern Hemisphere. Air then traveled from Laurasia (region of high pressure), across the Tethys Ocean to Gondwana (region of low pressure). Moisture advection toward the Southern Hemisphere would have fueled heavy precipitation along the Gondwana coasts, while Laurasia remained very dry.[4]

East Asian Monsoon compared to Pangean Megamonsoon

There are marked similarities between factors contributing to the East Asian monsoon and those that would have influenced Pangean climate. That supports the theory that Pangean climate was dominated by the monsoon and aids in its study by providing paleoclimatologists with a present-day example to which they can compare their findings.

Firstly, the width of the Tethys Ocean is believed to have been roughly the same as that of the Indian Ocean.[3] It is well-documented that the Indian Ocean can provide onshore-moving air masses with enough moisture to support a monsoon-driven environment. Thus, the Tethys should have been able to as well.

Additionally, many paleoclimate models have attempted to recreate climate patterns on Pangea. The models have yielded results that are comparable with the East Asian Monsoon. For instance, one model reported that the seasonal pressure differential (wintertime high pressure – summertime low pressure) over the continent was 25 millibars,[4] while the Asian pressure varies by 36 millibars on average throughout the year.[3]

It has also been noted Pangea possessed a mountain range that potentially played a similar role in the megamonsoon like that of the present Tibetan Plateau in the East Asian Monsoon.[3] Model simulations suggest that without the presence of the mountain range, the monsoon circulation would have been substantially weakened.[4] Higher elevations may have intensified the atmospheric circulation by maximizing the surface heating and subsequently the latent heat release during the summer rainy season.[8] There is still significant uncertainty regarding the extent of the impact that range would have had, however, because mountain elevations are still unknown.

Geologic record

Coal and evaporites

Coal is typically an indicator of moist climates since it needs both plant matter and humid conditions to form. The poleward progression of coal deposits with time suggests that the regions of maximum rainfall shifted away from the equator. Nonetheless, the employment coal as climatic indicator of precipitation is still employed with caution by geologists, as its creation secondarily depends on rainfall amounts.[3] When a significant amount of evaporation occurs, evaporites are formed, which therefore signifies arid conditions.

Loess

Loess, or windblown dust, can be used as an indicator of past atmospheric circulation patterns. Without the presence of the monsoon, surface winds across the globe would have been primarily zonal and easterly. The geologic record, however, indicates that winds exhibited a meridional cross-equatorial pattern but also that western Pangea experienced westerly flow during the peak period of the megamonsoon.[3][9][10]

Paleontological evidence

Fossils dating back to Pangean times also support the claim that a strongly-monsoonal circulation dominated the supercontinent’s climate. For example, tree rings (also called growth rings) provide convincing proof of distinct changes in annual weather patterns. Trees rooted in areas that do not experience seasonality will not exhibit rings within their trunks as they grow. Fossilized wood excavated from what was once coastal, mid-latitude Pangea, however, display the clear presence of rings.[2] Other paleoflora suggest that a significant portion of the year would have been dominated by a warm, moist season. Large, smooth leaf shapes with thin cuticles and symmetric distribution of stomata, as well as tropical fern species have been uncovered from those regions.[2]

The invertebrates and vertebrates that existed on Pangea offer further evidence of seasonality. For instance, unionid bivalve shells exhibit uniform banding patterns. Unionid bivalves were aquatic organisms that required shallow, oxygen-rich lakes to thrive. During the summer, when rain was persistent, their respiration occurred aerobically and precipitated calcium carbonate to grow their shells. In the winter, when precipitation ceased, the shallow aquatic environments within the Pangean continent began to dry up. Thus, unionid bivalves depleted their environments of oxygen and eventually had to resort to anaerobic processes for respiration. The anaerobic respiration yielded acidic waste, which reacted with the calcium carbonate shell, creating a darker ring and marking the presence of a distinct dry season. Once the summer rains returned, aerobic respiration was restored and calcium carbonate was once again produced. The transition from dry winters to rainy summers is therefore recorded in these alternating patterns of light and dark bands on the unionid bivalve shells.[2]

It has also been noted that the lungfish burrowing patterns correlate well with the rise and the fall of the water table.[2] The height of the water table would have increased during the rainy season, but then decreased rapidly as the winds shifted and diverted moisture away from the location, thus initiating the dry season. Additional evidence of seasonality can be observed in the fossilized carcasses of other vertebrate organisms. These show signs of substantial drying, which would have occurred during the winter, before they were buried and preserved by mudflow (resulting from a persistent rainy period).[2]

Evolution

Carboniferous

During much of the Carboniferous, the tropics would have experienced humid conditions, and the high latitudes of Gondwana were covered by glaciers.[11] Still, the first signs of the poleward movement of moisture arose during the late Carboniferous. Geologists have tracked regions of past coal accumulation as they began to be deposited further from the equator with time, evidence of a shift in precipitation patterns from the tropics toward the higher latitudes.[3] Still, land mass distribution remained more heavily concentrated in the Southern Hemisphere. Atmospheric flow, therefore, remained largely zonal,[12] indicating that the monsoon circulation had not yet begun to dominate the climatic pattern.

Permian

By Permian times, the monsoon circulation is apparent in the lithology. Winds with a westerly component (indicative of the summer monsoon, or wet season) are observed for the Early Permian.[13] The continents continued to drift northward. As they did so, the land mass became more evenly distributed across the equator and the megamonsoon continued to intensify.

Gondwana’s progression northward also influenced its gradual deglaciation.[14] Climate models indicate that low pressure systems strengthened as planetary ice cover decreased, thus exaggerating the effect of the monsoon. This also acted to magnify the aridity of the tropics. It is therefore suggested that glacial-interglacial patterns had a significant effect on the Pangean monsoonal circulation.[15] Models have also indicated that worldwide carbon dioxide substantially increased between Carboniferous and Permian times and resulted in increased temperatures.

Triassic

During the Triassic, the megamonsoon reached its maximum intensity, which is believed to be a result of the supercontinent attaining its largest surface area during this period from the final addition of present-day Siberia, Kazakhstan, southeast Asia, and fragments of China . Land mass was also equally distributed between the Northern and Southern Hemispheres, was nearly perfectly bisected by the equator, and extended from 85°N to 90°S.[3]

Both the increase in Pangean surface area and the equitable dissemination of the land mass across the hemispheres maximized surface heating during the summer.[3] The stronger the surface heating was, the more extreme the convection. By intensifying rising motion, the central pressure of the summertime surface low would have dropped. That, in turn, increased the hemispheric pressure gradient and amplified the cross-equatorial flow.

Additionally, the planet was experiencing a greenhouse climate during the Triassic, which resulted in continents completely devoid of ice, including the polar regions.[16] Interglacial periods correlate well with an intensification of the monsoon circulation.[17] Records clearly indicate a western component to the wind direction throughout this time period. It is also from that period that the paleontological evidence is most prevalent.[18][3]

Jurassic

During the early Jurassic, the supercontinent continued to shift northward. The coasts along the Tethys Ocean grew more persistently humid.[19] The monsoon circulation began to weaken through Jurassic time, due to Pangea’s break-up when the continents started to drift apart.[3] Records indicate that large-scale atmospheric flow progressively returned to a primarily zonal pattern.[5] Climatic patterns therefore became less extreme across the continents.

Future work

Today, the presence of the Pangean megamonsoon is generally accepted by the paleoclimate community. There is a substantial amount of evidence, both in the geologic record and model simulations, to support its existence.[4][2][3][20][21] Nevertheless, a significant amount of uncertainty still remains, particularly from a modeling perspective. One of the greater unknowns paleoclimatologists face is the impact of the Pangean mountain range. Model simulations have suggested that without the presence of the mountain range, the monsoon circulation would have been substantially weakened.[4] Geologists do know that Pangea did possess an extensive mountain range, which was probably comparable to the present-day Andes Mountains.[2]

Mountains were located to the north of the Tethys Ocean and resulted from the northward progression and subsequent subduction of the paleo-Tethyan plate.[2] However, the height of these mountains has yet to be quantified. Scientists have acknowledged that approximating their elevation is of “capital importance”.[22] Extremely high mountain ranges (rivaling the Himalayas) would have magnified atmospheric circulation, intensified the low pressure system, accelerated moisture transport to the coasts, and induced a rain shadow effect, promoting aridity on the leeward side of the range.[23]

Studies also continue to examine the impact of orbital cycles on the monsoon circulation.[24][4][25] The monsoon during the late Triassic appears to have been particularly impacted by Milankovich cycles for a period extending over at least 22 million years. Orbital eccentricity seems to have significantly affected precipitation cycles, but further research is required to better understand this correlation.[26]

Climate modelers are additionally trying to further understand and account for the surface and deep water circulations of the Panthalassic Ocean. The transport of heat resulting from these circulations significantly alters the simulated monsoon; therefore accurately representing them is of great importance.[4][27] Continued research will eventually provide scientists with a much more complete comprehension of the progression and behavior of the megamonsoon that dominated the Pangean climate.

References

  1. Smith, A.G. and R.A. Livermore: Pangea in Permian to Jurassic time. Tectonophysics, 187, 135-179.
  2. 2.0 2.1 2.2 2.3 2.4 2.5 2.6 2.7 2.8 Dubiel, Russell F; Parrish, Judith Totman; Parrish, J. Michael; Good, Steven (August 1991). "The Pangaean Megamonsoon—Evidence from the Upper Triassic Chinle Formation, Colorado Plateau". PALAIOS 6 (4): 347–370. doi:10.2307/3514963. Bibcode1991Palai...6..347D. http://digitalcommons.unl.edu/cgi/viewcontent.cgi?article=1227&context=usgsstaffpub. 
  3. 3.00 3.01 3.02 3.03 3.04 3.05 3.06 3.07 3.08 3.09 3.10 3.11 3.12 3.13 3.14 3.15 3.16 3.17 3.18 3.19 Parrish, Judith Totman (March 1993). "Climate of the Supercontinent Pangea". Journal of Geology 101 (2): 215–233. doi:10.1086/648217. Bibcode1993JG....101..215P. 
  4. 4.0 4.1 4.2 4.3 4.4 4.5 4.6 4.7 4.8 4.9 Kutzbach, Judith Totman; Gallimore, R.G. (20 March 1989). "Pangaean climates: Megamonsoons of the megacontinent". Journal of Geophysical Research 94 (D3): 3341-3357. doi:10.1029/JD094iD03p03341. 
  5. 5.0 5.1 5.2 Parrish, Judith Totman; Peterson, Fred (April 1988). "Wind directions predicted from global circulation models and wind directions determined from eolian sandstones of the western United States—A comparison". Sedimentary Geology 56 (1–4): 261-282. doi:10.1016/0037-0738(88)90056-5. 
  6. Soreghan, M.S., Soreghan, G.S., and Hamilton, M.A., 2002: Paleowinds inferred from detrital-zircon geochronology of upper Paleozoic loessite, western equatorial Pangea. Geology, 30, 695-698.
  7. Tabor, N.J. and I.P. Montañez, 2002: Shifts in late Paleozoic atmospheric circulation over western equatorial Pangaea: Insights from pedogenic mineral ɗ18O compositions. Geology, 30, 12, 1127-1130.
  8. Dubiel et al. 1991
  9. Soreghan, M.S., Soreghan, G.S., and Hamilton, M.A., 2002: Paleowinds inferred from detrital-zircon geochronology of upper Paleozoic loessite, western equatorial Pangea. Geology, 30, 695-698.
  10. Tabor, N.J. and I.P. Montañez, 2002: Shifts in late Paleozoic atmospheric circulation over western equatorial Pangaea: Insights from pedogenic mineral ɗ18O compositions. Geology, 30, 12, 1127-1130.
  11. Francis, J.E., 2009: Palaeoclimates of Pangea- geological evidence. Canadian Society of Petroleum Geologists, 17, 265-274.
  12. Francis, J.E., 2009: Palaeoclimates of Pangea- geological evidence. Canadian Society of Petroleum Geologists, 17, 265-274.
  13. Soreghan, M.S., Soreghan, G.S., and Hamilton, M.A., 2002: Paleowinds inferred from detrital-zircon geochronology of upper Paleozoic loessite, western equatorial Pangea. Geology, 30, 695-698.
  14. Francis, J.E., 2009: Palaeoclimates of Pangea- geological evidence. Canadian Society of Petroleum Geologists, 17, 265-274.
  15. Miller, K.B., T.J. McCahon, R.R. West, 1996: Lower Permian (Wolfcampiam) paleosols-bearing cycles of the U.S. Midcontinent: evidence of climatic cyclicity. Journal of Sedimentary Research, 66, 71-84.
  16. Olsen, P.E. and D.V. Kent, 1995: Milankovich climate forcing in the tropics of Pangea during the late Triassic. Palaeogeography, Palaeoclimatology, Palaeoecology, 122, 1-26.
  17. Francis, J.E., 2009: Palaeoclimates of Pangea- geological evidence. Canadian Society of Petroleum Geologists, 17, 265-274.
  18. Dubiel, R.F., J.T. Parrish, J.M. Parrish, S.C. Good, 1991: The Pangaean Megamonsoon—Evidence from the Upper Triassic Chinle Formation, Colorado Plateau. Society for Sedimentary Geology, 6, 347-370.
  19. Francis, J.E., 2009: Palaeoclimates of Pangea- geological evidence. Canadian Society of Petroleum Geologists, 17, 265-274.
  20. Soreghan, M.S., Soreghan, G.S., and Hamilton, M.A., 2002: Paleowinds inferred from detrital-zircon geochronology of upper Paleozoic loessite, western equatorial Pangea. Geology, 30, 695-698.
  21. Francis, J.E., 2009: Palaeoclimates of Pangea- geological evidence. Canadian Society of Petroleum Geologists, 17, 265-274.
  22. Fluteau, F., B.J. Broutin, and G. Ramstein, 2001: The late Permian climate. What can be inferred from climate modeling concerning Pangea scenarios and Hercynian range altitude? Palaeogeography, Palaeoclimatology, Palaeoecology, 167, 39-71.
  23. Fluteau, F., B.J. Broutin, and G. Ramstein, 2001: The late Permian climate. What can be inferred from climate modeling concerning Pangea scenarios and Hercynian range altitude? Palaeogeography, Palaeoclimatology, Palaeoecology, 167, 39-71.
  24. Olsen, P.E., 1986: A 40-million-yearlake record of early Mesozoic climate forcing. Science, 234, 842-848.
  25. Olsen, P.E. and D.V. Kent, 1995: Milankovich climate forcing in the tropics of Pangea during the late Triassic. Palaeogeography, Palaeoclimatology, Palaeoecology, 122, 1-26.
  26. Olsen, P.E. and D.V. Kent, 1995: Milankovich climate forcing in the tropics of Pangea during the late Triassic. Palaeogeography, Palaeoclimatology, Palaeoecology, 122, 1-26.
  27. Peyser, C.E and D.J. Poulsen, 2008: Controls on Permo-Carboniferous precipitation over tropical Pangaea: A GCM sensitivity study. Paleogeography, Paleaoclimatology, Paleoecology, 268, 181-192.

Sources

Crowley, T.J., W.T. Hyde, and D.A. Short, 1989: Seasonal cycle variations on the supercontinent of Pangaea. Geology, 17, 457-460.

Dubiel, R.F., J.T. Parrish, J.M. Parrish, S.C. Good, 1991: The Pangaean Megamonsoon—Evidence from the Upper Triassic Chinle Formation, Colorado Plateau. Society for Sedimentary Geology, 6, 347-370.

Fluteau, F., B.J. Broutin, and G. Ramstein, 2001: The late Permian climate. What can be inferred from climate modeling concerning Pangea scenarios and Hercynian range altitude? Palaeogeography, Palaeoclimatology, Palaeoecology, 167, 39-71

Francis, J.E., 2009: Palaeoclimates of Pangea- geological evidence. Canadian Society of Petroleum Geologists, 17, 265-274.

Kutzbach, J.E. and R.G. Gallimore, 1989: Pangaean climates: Megamonsoons of the megacontinent. Journal of Geophysical Research, 94, 3341-3357.

Miller, K.B., T.J. McCahon, R.R. West, 1996: Lower Permian (Wolfcampiam) paleosols-bearing cycles of the U.S. Midcontinent: evidence of climatic cyclicity. Journal of Sedimentary Research, 66, 71-84.

Montañez, I.P., N.J. Tabor, D. Niemeier et al., 2007: CO2-Forced climate and vegetation instability during late Paleozoic deglaciation. Science, 315, 87-91.

Parrish, J. T., 1993: Climate of the Supercontinent Pangea. Journal of Geology, 10, 215-233.

Parrish, J.T. and F. Peterson, 1988: Wind directions predicted from global circulation models and wind directions determined from eolian sandstones of the western United States—a comparison. Sedimentary Geology, 56, 261-282.

Peyser, C.E and D.J. Poulsen, 2008: Controls on Permo-Carboniferous precipitation over tropical Pangaea: A GCM sensitivity study. Paleogeography, Paleaoclimatology, Paleoecology, 268, 181-192.

Olsen, P.E., 1986: A 40-million-yearlake record og early Mesozoic climate forcing. Science, 234, 842-848.

Olsen, P.E. and D.V. Kent, 1995: Milankovich climate forcing in the tropics of Pangea during the late Triassic. Palaeogeography, Palaeoclimatology, Palaeoecology, 122, 1-26.

Tabor, N.J. and I.P. Montañez, 2002: Shifts in late Paleozoic atmospheric circulation over western equatorial Pangaea: Insights from pedogenic mineral ɗ18O compositions. Geology, 30, 12, 1127-1130.

Smith, A.G. and R.A. Livermore: Pangea in Permian to Jurassic time. Tectonophysics, 187, 135-179.

Soreghan, M.S., Soreghan, G.S., and Hamilton, M.A., 2002: Paleowinds inferred from detrital-zircon geochronology of upper Paleozoic loessite, western equatorial Pangea. Geology, 30, 695-698.

Valentine, J.W. and E.M. Moores, 1970: Plate-tectonic regulation of faunal diversity and sea level: a model. Nature, 22, 657-659.



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