Long-period astronomical forcing of mammal turnover

Mammals are among the fastest-radiating groups, being characterized by a mean species lifespan of the order of 2.5 million years (Myr). The basis for this characteristic timescale of origination, extinction and turnover is not well understood. Various studies have invoked climate change to explain m...

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Published inNature (London) Vol. 443; no. 7112; pp. 687 - 691
Main Authors van der Meulen, Albert J, Abdul Aziz, Hayfaa, Hilgen, Frederik J, van den Hoek Ostende, Lars W, Lourens, Lucas J, Ángeles Álvarez Sierra, M, Mein, Pierre, Pelaez-Campomanes, Pablo, van Dam, Jan A
Format Journal Article
LanguageEnglish
Published London Nature Publishing 12.10.2006
Nature Publishing Group
Subjects
Animals
Biodiversity
Biological Evolution
Climate
Climate change
Earth Sciences
Earth, ocean, space
Exact sciences and technology
Genetics
History, Ancient
Ice Cover
Life cycles
Life span
Mammals
Paleontology
Rodentia - physiology
Rodents
Sciences of the Universe
Spain
Time Factors
Vertebrate paleontology
Iberian Peninsula
Southern Europe
Spain
Chordata
atmospheric precipitation
Europe
Rodentia
eccentricity
cycles
evolution
Eutheria
expansion
Vertebrata
extinction
ice sheets
Mammalia
climate modification
periodicity
Theria
Milankovitch theory
skewness
climate cooling
oscillations
Tetrapoda
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Summary:Mammals are among the fastest-radiating groups, being characterized by a mean species lifespan of the order of 2.5 million years (Myr). The basis for this characteristic timescale of origination, extinction and turnover is not well understood. Various studies have invoked climate change to explain mammalian species turnover, but other studies have either challenged or only partly confirmed the climate-turnover hypothesis. Here we use an exceptionally long (24.5-2.5 Myr ago), dense, and well-dated terrestrial record of rodent lineages from central Spain, and show the existence of turnover cycles with periods of 2.4-2.5 and 1.0 Myr. We link these cycles to low-frequency modulations of Milankovitch oscillations, and show that pulses of turnover occur at minima of the 2.37-Myr eccentricity cycle and nodes of the 1.2-Myr obliquity cycle. Because obliquity nodes and eccentricity minima are associated with ice sheet expansion and cooling and affect regional precipitation, we infer that long-period astronomical climate forcing is a major determinant of species turnover in small mammals and probably other groups as well.
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ISSN:0028-0836
1476-4687
DOI:10.1038/nature05163