Margaret E. Collinson scite author profile

During the end-Permian ecological crisis, terrestrial ecosystems experienced preferential dieback of woody vegetation. Across the world, surviving herbaceous lycopsids played a pioneering role in repopulating deforested terrain. We document that the microspores of these lycopsids were regularly released in unseparated tetrads indicative of failure to complete the normal process of spore development. Although involvement of mutation has long been hinted at or proposed in theory, this finding provides concrete evidence for chronic environmental mutagenesis at the time of global ecological crisis. Prolonged exposure to enhanced UV radiation could account satisfactorily for a worldwide increase in land plant mutation. At the end of the Permian, a period of raised UV stress may have been the consequence of severe disruption of the stratospheric ozone balance by excessive emission of hydrothermal organohalogens in the vast area of Siberian Traps volcanism.

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Cainozoic ferns and their distribution

Collinson

2001

Brittonia

182

119

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Cretaceous wildfires and their impact on the Earth system

Brown

Scott

Glasspool

et al. 2012

Cretaceous Research

127

114

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Constraints on the thermal energy released from the Chicxulub impactor: new evidence from multi-method charcoal analysis

Belcher

Collinson

Scott

2005

JGS

103

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Terrestrial cooling in Northern Europe during the Eocene–Oligocene transition

Hren

Sheldon

Grimes

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

111

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Geochemical and modeling studies suggest that the transition from the "greenhouse" state of the Late Eocene to the "icehouse" conditions of the Oligocene 34-33.5 Ma was triggered by a reduction of atmospheric pCO 2 that enabled the rapid buildup of a permanent ice sheet on the Antarctic continent. Marine records show that the drop in pCO 2 during this interval was accompanied by a significant decline in high-latitude sea surface and deep ocean temperature and enhanced seasonality in middle and high latitudes. However, terrestrial records of this climate transition show heterogeneous responses to changing pCO 2 and ocean temperatures, with some records showing a significant time lag in the temperature response to declining pCO 2 . We measured the Δ 47 of aragonite shells of the freshwater gastropod Viviparus lentus from the Solent Group, Hampshire Basin, United Kingdom, to reconstruct terrestrial temperature and hydrologic change in the North Atlantic region during the Eocene-Oligocene transition. Our data show a decrease in growing-season surface water temperatures (∼10°C) during the Eocene-Oligocene transition, corresponding to an average decrease in mean annual air temperature of ∼4-6°C from the Late Eocene to Early Oligocene. The magnitude of cooling is similar to observed decreases in North Atlantic sea surface temperature over this interval and occurs during major glacial expansion. This suggests a close linkage between atmospheric carbon dioxide concentrations, Northern Hemisphere temperature, and expansion of the Antarctic ice sheets.clumped isotopes | paleoclimate T he Eocene-Oligocene transition 34-33.5 Ma represents one of the most dramatic climatic changes of the past 65 My (1-3). Studies suggest that by 34 Ma, pCO 2 reached a critical threshold where favorable orbital parameters and ocean circulation patterns allowed the rapid buildup of Antarctic ice, triggering widespread reduction in atmospheric pCO 2 and decreases in sea surface and deep ocean temperature (4-8). This event is marked by a +1.5‰ shift in the oxygen isotope ratios of carbonate from deep-sea benthic foraminifera, which reflects both the glaciation of Antarctica and rapid cooling of the surface and deep ocean (1, 3).Marine sediments provide high-resolution records of surface and deep ocean temperature responses to the Late Eocene decreases in pCO 2 and Antarctic glaciation (7,8). These show that cooling was amplified in high-latitude regions, with a decrease in sea surface temperature of >5°C from the Late Eocene to Early Oligocene (7). Tropical sea surface temperature (SST) and deep ocean records show mixed responses to global cooling across the Eocene-Oligocene transition (EOT), with some indicating only modest declines in temperature in the tropics (8) and others showing a 3-4°C decrease in SST during the first stage of the cooling event (EOT-1) (9). One recent multiproxy study suggests that cooling during the EOT was specifically linked to increased seasonality, with the majority of cooling occurring during the coolseason months (...

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Experiments in waterlogging and sedimentology of charcoal: results and implications

Nichols

Cripps

Collinson

et al. 2000

Palaeogeography, Palaeoclimatology, Palaeoecology

140

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Eocene–Oligocene mammalian faunal turnover in the Hampshire Basin, UK: calibration to the global time scale and the major cooling event

Hooker

Collinson

Sille

2004

JGS

118

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A new high-resolution, c. 1 Ma mammalian record in continental Eocene-Oligocene strata in the Hampshire Basin is used to investigate the nature and timing of the major Europe-wide mammalian faunal turnover termed the Grande Coupure. Whether this was caused by climate change or by competition with taxa dispersing from Asia is controversial. The mammalian faunas in this record, after rarefaction analysis, show a sharp reduction in diversity only after the Grande Coupure. Improved correlation of NW European successions to global events confirms the Grande Coupure as earliest Oligocene. It shows that a c. 350 ka hiatus interrupts the Hampshire and Paris Basin sequences prior to the first record of post-Grande Coupure Asian taxa. Hiatusbridging faunas from elsewhere in Europe record mainly post-Grande Coupure taxa, suggesting that the turnover occurred early in the hiatus, minimizing bias to the turnover pattern. A previously unrecorded, second, smaller turnover, involving European mammals only, immediately precedes the Grande Coupure in the Hampshire Basin, coinciding with vegetational change. This turnover is judged not to represent cooling. It is concluded that the Grande Coupure coincides with the earliest Oligocene Oi-1 glaciation and that climate change combined with competition to produce the turnover.

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