The last three millions of unequal spring thaws

Evidence from various climate proxies provides us with increasingly reliable proof that only in the past 10 millennia were natural systems more or less as we see them at the present (without considering human impact). Prior to 10,000 years ago, natural systems repeatedly changed under the influence...

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Main Authors: Martinetto, Edoardo, Bertini, Adele, Bhandari, Sudarshan, Bruch, Angela A., Cerilli, Eugenio, Cherin, Marco, Field, Judith H., Gabrielyan, Ivan, Gianotti, Franco, Kern, Andrea K., Kienast, Frank, Lindsey, Emily L., Momohara, Arata, Ravazzi, Cesare, Thomas, Elizabeth R.
Other Authors: Martinetto, E., Tschopp, E., Gastaldo, R.
Format: Book Part
Language:unknown
Published: Springer 2020
Subjects:
Greenland
Antarc*
Antarctica
Online Access:http://nora.nerc.ac.uk/id/eprint/528276/
https://link.springer.com/chapter/10.1007/978-3-030-35058-1_1
id ftnerc:oai:nora.nerc.ac.uk:528276
record_format openpolar
spelling ftnerc:oai:nora.nerc.ac.uk:528276 2023-05-15T13:41:45+02:00 The last three millions of unequal spring thaws Martinetto, Edoardo Bertini, Adele Bhandari, Sudarshan Bruch, Angela A. Cerilli, Eugenio Cherin, Marco Field, Judith H. Gabrielyan, Ivan Gianotti, Franco Kern, Andrea K. Kienast, Frank Lindsey, Emily L. Momohara, Arata Ravazzi, Cesare Thomas, Elizabeth R. Martinetto, E. Tschopp, E. Gastaldo, R. 2020 http://nora.nerc.ac.uk/id/eprint/528276/ https://link.springer.com/chapter/10.1007/978-3-030-35058-1_1 unknown Springer Martinetto, Edoardo; Bertini, Adele; Bhandari, Sudarshan; Bruch, Angela A.; Cerilli, Eugenio; Cherin, Marco; Field, Judith H.; Gabrielyan, Ivan; Gianotti, Franco; Kern, Andrea K.; Kienast, Frank; Lindsey, Emily L.; Momohara, Arata; Ravazzi, Cesare; Thomas, Elizabeth R. orcid:0000-0002-3010-6493 . 2020 The last three millions of unequal spring thaws. In: Martinetto, E.; Tschopp, E.; Gastaldo, R., (eds.) Nature through Time. Cham, Springer, 53pp. (Springer Textbooks in Earth Sciences, Geography and Environment). Publication - Book Section PeerReviewed 2020 ftnerc 2023-02-04T19:50:59Z Evidence from various climate proxies provides us with increasingly reliable proof that only in the past 10 millennia were natural systems more or less as we see them at the present (without considering human impact). Prior to 10,000 years ago, natural systems repeatedly changed under the influence of an unstable climate. This is particularly true over the last one million years. During these times, terrestrial environments were populated by a diversity of large animals that did not survive either the last dramatic climate change or the increasing power of humans. The volume of continental ice covering the land and its impact on the planet’s physiography∗ and vegetation have varied consistently. We can try to imagine extreme conditions: the very cold springtimes of the full glacials∗, and the warm springtimes of the rapid deglaciation phases, with enormous volumes of water feeding terrifying rivers. Most of this story is frozen in the ice cover of Greenland and Antarctica, the deep layers of which have been reached by human coring activities only over the past half century. Shorter cores have been drilled in high-altitude ice caps (e.g., in the Andes) that provide insight into other parts of the planet. The interpretation of the signals locked into the ice cores led to the reconstruction of climatic curves covering approximately the past 800 millennia. In addition, long sediment cores have been recovered from thousands of lakes across the globe and yielded data useful to estimate climatic trends based on pollen* records. In the past one to three million years, the continents and oceans were in roughly their present-day locations. Environmental factors, including tectonics (mountain uplift or closure of ocean gateways), interacted with the overall long-term oscillation in atmospheric carbon-dioxide concentration, which, in turn, influenced vegetation cover and ecosystem composition. Well-established glacial-interglacial∗ cycles impacted biotic dispersal∗ events at mid-to-high latitudes and determined the ... Book Part Antarc* Antarctica Greenland Natural Environment Research Council: NERC Open Research Archive Greenland
institution Open Polar
collection Natural Environment Research Council: NERC Open Research Archive
op_collection_id ftnerc
language unknown
description Evidence from various climate proxies provides us with increasingly reliable proof that only in the past 10 millennia were natural systems more or less as we see them at the present (without considering human impact). Prior to 10,000 years ago, natural systems repeatedly changed under the influence of an unstable climate. This is particularly true over the last one million years. During these times, terrestrial environments were populated by a diversity of large animals that did not survive either the last dramatic climate change or the increasing power of humans. The volume of continental ice covering the land and its impact on the planet’s physiography∗ and vegetation have varied consistently. We can try to imagine extreme conditions: the very cold springtimes of the full glacials∗, and the warm springtimes of the rapid deglaciation phases, with enormous volumes of water feeding terrifying rivers. Most of this story is frozen in the ice cover of Greenland and Antarctica, the deep layers of which have been reached by human coring activities only over the past half century. Shorter cores have been drilled in high-altitude ice caps (e.g., in the Andes) that provide insight into other parts of the planet. The interpretation of the signals locked into the ice cores led to the reconstruction of climatic curves covering approximately the past 800 millennia. In addition, long sediment cores have been recovered from thousands of lakes across the globe and yielded data useful to estimate climatic trends based on pollen* records. In the past one to three million years, the continents and oceans were in roughly their present-day locations. Environmental factors, including tectonics (mountain uplift or closure of ocean gateways), interacted with the overall long-term oscillation in atmospheric carbon-dioxide concentration, which, in turn, influenced vegetation cover and ecosystem composition. Well-established glacial-interglacial∗ cycles impacted biotic dispersal∗ events at mid-to-high latitudes and determined the ...
author2 Martinetto, E.
Tschopp, E.
Gastaldo, R.
format Book Part
author Martinetto, Edoardo
Bertini, Adele
Bhandari, Sudarshan
Bruch, Angela A.
Cerilli, Eugenio
Cherin, Marco
Field, Judith H.
Gabrielyan, Ivan
Gianotti, Franco
Kern, Andrea K.
Kienast, Frank
Lindsey, Emily L.
Momohara, Arata
Ravazzi, Cesare
Thomas, Elizabeth R.
spellingShingle Martinetto, Edoardo
Bertini, Adele
Bhandari, Sudarshan
Bruch, Angela A.
Cerilli, Eugenio
Cherin, Marco
Field, Judith H.
Gabrielyan, Ivan
Gianotti, Franco
Kern, Andrea K.
Kienast, Frank
Lindsey, Emily L.
Momohara, Arata
Ravazzi, Cesare
Thomas, Elizabeth R.
The last three millions of unequal spring thaws
author_facet Martinetto, Edoardo
Bertini, Adele
Bhandari, Sudarshan
Bruch, Angela A.
Cerilli, Eugenio
Cherin, Marco
Field, Judith H.
Gabrielyan, Ivan
Gianotti, Franco
Kern, Andrea K.
Kienast, Frank
Lindsey, Emily L.
Momohara, Arata
Ravazzi, Cesare
Thomas, Elizabeth R.
author_sort Martinetto, Edoardo
title The last three millions of unequal spring thaws
title_short The last three millions of unequal spring thaws
title_full The last three millions of unequal spring thaws
title_fullStr The last three millions of unequal spring thaws
title_full_unstemmed The last three millions of unequal spring thaws
title_sort last three millions of unequal spring thaws
publisher Springer
publishDate 2020
url http://nora.nerc.ac.uk/id/eprint/528276/
https://link.springer.com/chapter/10.1007/978-3-030-35058-1_1
geographic Greenland
geographic_facet Greenland
genre Antarc*
Antarctica
Greenland
genre_facet Antarc*
Antarctica
Greenland
op_relation Martinetto, Edoardo; Bertini, Adele; Bhandari, Sudarshan; Bruch, Angela A.; Cerilli, Eugenio; Cherin, Marco; Field, Judith H.; Gabrielyan, Ivan; Gianotti, Franco; Kern, Andrea K.; Kienast, Frank; Lindsey, Emily L.; Momohara, Arata; Ravazzi, Cesare; Thomas, Elizabeth R. orcid:0000-0002-3010-6493 . 2020 The last three millions of unequal spring thaws. In: Martinetto, E.; Tschopp, E.; Gastaldo, R., (eds.) Nature through Time. Cham, Springer, 53pp. (Springer Textbooks in Earth Sciences, Geography and Environment).
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