The Late Ordovician Mass Extinction (LOME) coincided with dramatic climate changes, but there are numerous ways in which these changes could have driven marine extinctions. We use a palaeobiogeographic database of rhynchonelliform brachiopods to examine the selectivity of Late Ordovician – Early Silurian genus extinctions and evaluate which extinction drivers are best supported by the data. The first (latest Katian) pulse of the LOME preferentially affected genera restricted to deeper waters or to relatively narrow (< 35°) palaeolatitudinal ranges. This pattern is only observed in the latest Katian, suggesting that it reflects drivers unique to this interval. Extinction of exclusively deeper-water genera implies that changes in water mass p...
Selectivity patterns provide insights into the causes of ancient extinction events. The Late Ordovic...
Mass extinctions can have dramatic effects on the trajectory of life, but in some cases the effects ...
The geographic distribution of brachiopod genus occurrences over the Phanerozoic shows that secular ...
The Late Ordovician Mass Extinction (LOME) coincided with dramatic climate changes, but there are nu...
The Late Ordovician mass extinction (LOME) coincided with dramatic climate changes, but there are nu...
The Late Ordovician mass extinction (LOME) coincided with dramatic climate changes, but there are nu...
The Late Ordovician mass extinction (LOME) coincided with dramatic climate changes, but there are nu...
The Late Ordovician mass extinction was an interval of high extinction with inferred low ecological ...
Mass extinctions affect the history of life by decimating existing diversity and ecological structur...
A basic hypothesis in extinction theory predicts that more abundant taxa have an evolutionary advant...
Mass extinctions can have dramatic effects on the trajectory of life, but in some cases the effects ...
Mass extinction events are recognized by increases in extinction rate and magnitude and, often, by c...
Mass extinction events are recognized by increases in extinction rate and magnitude and, often, by c...
Mass extinction events are recognized by increases in extinction rate and magnitude and, often, by c...
Selectivity patterns provide insights into the causes of ancient extinction events. The Late Ordovic...
Mass extinctions can have dramatic effects on the trajectory of life, but in some cases the effects ...
The geographic distribution of brachiopod genus occurrences over the Phanerozoic shows that secular ...
The Late Ordovician Mass Extinction (LOME) coincided with dramatic climate changes, but there are nu...
The Late Ordovician mass extinction (LOME) coincided with dramatic climate changes, but there are nu...
The Late Ordovician mass extinction (LOME) coincided with dramatic climate changes, but there are nu...
The Late Ordovician mass extinction (LOME) coincided with dramatic climate changes, but there are nu...
The Late Ordovician mass extinction was an interval of high extinction with inferred low ecological ...
Mass extinctions affect the history of life by decimating existing diversity and ecological structur...
A basic hypothesis in extinction theory predicts that more abundant taxa have an evolutionary advant...
Mass extinctions can have dramatic effects on the trajectory of life, but in some cases the effects ...
Mass extinction events are recognized by increases in extinction rate and magnitude and, often, by c...
Mass extinction events are recognized by increases in extinction rate and magnitude and, often, by c...
Mass extinction events are recognized by increases in extinction rate and magnitude and, often, by c...
Selectivity patterns provide insights into the causes of ancient extinction events. The Late Ordovic...
Mass extinctions can have dramatic effects on the trajectory of life, but in some cases the effects ...
The geographic distribution of brachiopod genus occurrences over the Phanerozoic shows that secular ...