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Quaternary science

From Wikipedia, the free encyclopedia

Quaternary science is the subfield of geology which studies the Quaternary Period commonly known as the ice age. The Quaternary Period is a time period that started around 2.58 million years ago and continues today.[1][2] This period is divided into two epochs – the Pleistocene Epoch and the Holocene Epoch. The aim of Quaternary science is to understand everything that happened during the Pleistocene Epoch and the Holocene Epoch to be able to acquire fundamental knowledge about Earth's environment, ecosystem, climate changes, etc. Quaternary science was first studied during the nineteenth century by Georges Cuvier, a French scientist. Most Quaternary scientists have studied the history of the Quaternary to predict future changes in climate.[citation needed]

Quaternary science plays a vital role in archaeology providing a possible accurate human studies' framework which would help the archaeologists interpret archaeological records.[3]

Definition

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Quaternary science is the systematic study of the Quaternary Period. It is a rapidly changing field with new research techniques being developed e.g. new dating techniques. Quaternary science is a field of study which involves geography, biology, chemistry, and physics.[4] Its focus is during the Quaternary Period – a time period that started around 2.58 million years ago and which continues to the present day.[1] Earth has been affected by the events that occurred during the Quaternary Period – a time of ice ages. One topic in Quaternary science is to understand what happened during the ice ages. Quaternary science adds an important historical perspective to the understanding of current ecosystems and climate changes.[4]

History

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Georges Cuvier

The Quaternary Period is a geologic time period that can be separated into two epochs, the Pleistocene ("most recent") Epoch, generally defined as beginning about 2.58 million years ago, and the Holocene ("wholly modern") Epoch, which began about 11,700 years ago.[5][6]

The study of Quaternary science began in the late eighteenth century in Europe. The term 'Quaternary' was first used by Italian engineer Giovanni Arduino to describe the four most recent geologic eras. It later became clear that the term ‘Quaternary’ as described by Meadows and Finch (2016) was "a phase of highly variable climates, with marked periods of time when global temperatures were significantly lower than today and evidence for which was interpreted by Louis Agassiz as indications of a geologically recent ‘Great Ice Age’".[4][7]

The study of Quaternary science was first demonstrated by early nineteenth century French scientist Georges Cuvier. He proposed that some animals that lived in the Pleistocene epoch were made extinct by some environmental ‘revolution’ (e.g. some catastrophic flooding events). It was this insight that made him famous.[4]

Theory regarding the causation of ice ages also developed during this period. The first theory to come out was the theory of how the variation of Earth's orbit affect the global climate by James Croll, a Scottish scientist. James Croll was the first person to ever recognize the significance of positive feedbacks in the climate system, including the feedbacks of ice-albedo. Furthermore, his theory was also the first theory to predict the cause of glaciation.[8]

It was during the twentieth century that this idea was further elaborated. Milutin Milankovitch, a Serbian mathematician and geophysicist, was best known for his theory which involved the motion of the Earth and their relationship to long-term climate changes. One of early calculations of Milankovitch offered information about the changes in incident solar radiation (as a function of season) for millions of years. In addition, André Berger – a Belgian professor and climatologist, also identified the certain time period where reconstructed insolation was higher than the average or lower than the average. Many of his analyses show that from May to August, there has been a forwarded shift of insolation maximum (higher than average) in the late Quaternary insolation variation. This feature is known as "insolation signature" and may have possible relationship with the changes in climate as contemplated by Berger.[9]

During the twentieth century important sub-disciplines of Quaternary science, such as palaeoecology, palaeontology and palaeoclimatology, revealed relationships between changes in the environment and the planet's history during its Quaternary Period.

Latest developments

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There are many studies of Quaternary science being researched in the present. As stated before, Quaternary science is rapidly changing field, hence why there are always new researches being studied and published – providing evidences and establishing new techniques. One of the latest researches was the study about the "Late Pleistocene–Holocene environmental and climatic history of a freshwater paramo ecosystem in the northern Andes" where the researchers study the palaeoclimatic history of the Northern South America based on the palaeolimnological reconstruction of a pond.[10] Another recent study would be the study of "Molecular fossils as a tool for tracking Holocene sea‐level change in the Loch of Stenness, Orkney" by Conti, Bates, Preece, Penkman, and Keely (2020), in which they study how molecular fossils could be used as an approach to study past sea-level change.[11] There are still many more researches being done right now. After all, Quaternary science is the study of our history spanning the last 2.58 million years, there are so many things left to be discovered.

An Evidence of Human History in Archaeology Museum

Quaternary science also played an important role in another area of science – archaeology. Archaeology is the field of science which uses material remains to study the human past. There are many types of archaeology as this field of study is a diverse field. Some archaeologists study the remains of the human – bioarchaeology, some study the ancient plants – paleoethnobotany, and some even study the stone tools. Furthermore, not every archaeologist is specialized in the same area, some archaeologist specialized in technologies which help located a map or sites, while some are a specialist in studying human remains underwater.[12] Quaternary science has offered a precise and comprehensive framework to human studies which help the global interpretation of the archaeological records in the field of archaeology. For an illustration, some of the commonly known frameworks which contributed to the global interpretation of the records are chronology, palaeoenvironmental background and site formation processes.[3]

One of the important focuses of Quaternary science in archaeology is the study of geochronology. Geochronology is the study of science concerning the ages and dates of Earth's material (e.g. rocks, fossils, etc.) and events.[13] This area of research was deemed to be very significant to the archaeology of Indigenous Australia due to the fact that there are very few cultural markers that can be used for the relative chronology. The relative chronology in archaeology is normally used in places that are easily identified on the archaeological records and have a strong differentiation in cultural productions. In addition to focusing on geochronology, the key role of Quaternary science to archaeology is to help the archaeologists in resolving some of their major problems relating to its impact on the surrounding environment, the Colonization of human in the past, cultural productions, and its mobility. Quaternary science offers the archaeologist invaluable data which assist them in further understanding the environment and landscape which involved the evolution of the humans during the late Quaternary Period.[3]

Socio-economic impact

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Quaternary science has wide-ranging effects, studying things such as the impact of climate changes on animals and human, adaptation of living organisms, and human evolution. A species’ adapting to new changes is a sign that it has been impacted by something. In this case, it is how organisms respond to climate changes. To be able to live, develop, and continue to reproduce, every species relies on upon its ecological requirements – including their environmental factors (climates, geology, etc. However, not all species respond in the same ways when changes happened. Adaptation allows species to evolve to be able to live in the same place despite the climate change. Some adaptations even involve genetic modification. The impact of climate shift has caused species to modify their genome to survive.[14]

Aceraceae

Research was done to examine whether there are any impacts of the pre-Quaternary Period and Quaternary Period on contemporary species richness. Species richness is the number of various species that exist in a certain locations or landscape.[15] The aim of the researchers here is to analyze the roles of the Quaternary climatic oscillations and pre-Quaternary legacies in influencing the worldwide distribution and palm diversity pattern (Aceraceae), and the ecological importance of a diverse group of keystone species in its tropical ecosystem. In the experiment, researchers gathered lists of almost every international species and assembled any related or connected data on possible climates during the Quaternary Period, modern-day environment drivers (such as our current climate, habitat, area, etc.), and vital biogeographic land to gauge the extent to which the global distribution and the patterns of species richness in palms reflect the effect of Quaternary climatic movement and pre-Quaternary legacies. After the experiment, they discovered that Quaternary climates change has significantly affected the richness of the palm species. Moreover, they found out that the global constraint on the distribution of the palm family was influenced by the current climate, whereas the climate during the Quaternary Period only caused a slight constraint.[16]

From many researches, climate changes during the Quaternary Period have impacted the life of many species living in the present day. The research by Silva, Antonelli, Lendel, Moraes, and Manfrin (2018) in Southeastern United States suggests that there was a major impact of the early Quaternary climate change on the spreading and diversity of the Cactus species of South America.[17] Additionally, not only the Quaternary science impacted the plant species and animal species, they also caused some ecological state shift.[18]

An article researched by Barnosky, Lindsey, Villavicencio, et al. (2016) provides evidence which support the findings that megafaunal extinction during the late Quaternary Period has a huge effect in causing several ecological state shifts in North and South America. The loss of megafauna species has caused ecological change over a period of time. The purpose of the research is to examine whether the loss of megafauna species during the ice age could explain the phenomenon of ecological state shifts that have happened as the Pleistocene Epoch gave way to the Holocene Epoch. From their findings, they learned that should large species went extinct like the megafauna, our current ecosystem would be at risk of disappearing. The reason is that, in the megafauna case, those species must have been an effective ecosystem engineer and as a respond to the extinction of megafauna, possible events must have occurred to provide our ecosystem with more plant species, thus, triggering a lasting ecological state shift.[18]

Academic journals

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See also

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References

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  1. ^ a b Bagley, Mary (February 2014). "Quaternary Period: Climate, Animals & Other Facts". livescience.com. Retrieved 30 September 2020.
  2. ^ "Stratigraphic Chart 2022" (PDF). International Stratigraphic Commission. February 2022. Retrieved 4 June 2022.
  3. ^ a b c Vannieuwenhuyse, Dorcas (2014). "Role of Quaternary science in archaeology". Quaternary Australasia. 31 (2): 9–10.
  4. ^ a b c d Elias, Scott (2007). Encyclopedia of quaternary science (1st ed.). Elsevier.
  5. ^ Bagley, Mary (March 2013). "Holocene Epoch: The Age of Man". livescience.com. Retrieved 6 October 2020.
  6. ^ Zimmermann, Kim Ann (August 2017). "Pleistocene Epoch: Facts About the Last Ice Age". livescience.com. Retrieved 29 October 2020.
  7. ^ Meadows, Michael E; Finch, Jemma M (2016). "The history and development of Quaternary Science in South Africa". South African Geographical Journal. 98 (3): 472–482. doi:10.1080/03736245.2016.1208587. ISSN 0373-6245. S2CID 133335346.
  8. ^ Bol'shakov, V.A.; Kapitsa, A.P.; Rees, W.G. (8 July 2011). "James Croll: a scientist ahead of his time". Polar Record. 48 (2): 201–205. doi:10.1017/s0032247411000301. ISSN 0032-2474. S2CID 131661899.
  9. ^ Dawson, Alastair G. (17 June 2013). Ice Age Earth: Late Quaternary Geology and Climate (0 ed.). Routledge. doi:10.4324/9780203713501. ISBN 978-0-203-71350-1.
  10. ^ Patiño, Luisa; Velez, Maria Isabel; Weber, Marion; Velásquez‐r, César A.; David, Santiago; Rueda, Manuela; Castañeda, Ivonne; Arboleda, Diana (30 September 2020). "Late Pleistocene–Holocene environmental and climatic history of a freshwater paramo ecosystem in the northern Andes". Journal of Quaternary Science. 35 (8): 1046–1056. doi:10.1002/jqs.3249. ISSN 0267-8179. S2CID 225006877.
  11. ^ Conti, Martina L. G.; Bates, Martin R.; Preece, Richard C.; Penkman, Kirsty E. H.; Keely, Brendan J (2020). "Molecular fossils as a tool for tracking Holocene sea‐level change in the Loch of Stenness, Orkney". Journal of Quaternary Science. 35 (7): 881–891. doi:10.1002/jqs.3238. S2CID 225337184.
  12. ^ "What is Archaeology?". Society for American Archaeology. Retrieved 29 October 2020.
  13. ^ "Geochronology". Rates and Time. 2020. Retrieved 31 October 2020.
  14. ^ Rull, Valentí (2020). Quaternary Ecology, Evolution, and Biogeography. Academic Press.
  15. ^ Adams, Jonathan (2009). Species Richness: Patterns in the Diversity of Life. Berlin, Heidelberg: Springer.
  16. ^ Kissling, W. Daniel; Baker, William J.; Balslev, Henrik; Barfod, Anders S.; Borchsenius, Finn; Dransfield, John; Govaerts, Rafaël; Svenning, Jens-Christian (2012). "Quaternary and pre-Quaternary historical legacies in the global distribution of a major tropical plant lineage". Global Ecology and Biogeography. 21 (9/10): 909–921. doi:10.1111/j.1466-8238.2011.00728.x. ISSN 1466-822X. JSTOR 23326646.
  17. ^ Silva, Gislaine Angélica Rodrigues; Antonelli, Alexandre; Lendel, Anita; Moraes, Evandro de Marsola; Manfrin, Maura Helena (7 November 2017). "The impact of early Quaternary climate change on the diversification and population dynamics of a South American cactus species". Journal of Biogeography. 45 (1): 76–88. doi:10.1111/jbi.13107. ISSN 0305-0270. S2CID 89652241.
  18. ^ a b Barnosky, Anthony D.; Lindsey, Emily L.; Villavicencio, Natalia A.; Bostelmann, Enrique; Hadly, Elizabeth A.; Wanket, James; Marshall, Charles R. (26 October 2015). "Variable impact of late-Quaternary megafaunal extinction in causing ecological state shifts in North and South America". Proceedings of the National Academy of Sciences. 113 (4): 856–861. doi:10.1073/pnas.1505295112. ISSN 0027-8424. PMC 4739530. PMID 26504219.
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