Book contents
- Frontmatter
- Contents
- List of contributors
- Preface
- 1 Introduction
- 2 The Cretaceous world
- 3 The Cenozoic world
- 4 Calcareous nannoplankton and global climate change
- 5 Phenotypic response of foraminifera to episodes of global environmental change
- 6 The response of planktonic foraminifera to the Late Pliocene intensification of Northern Hemisphere glaciation
- 7 The response of Cretaceous cephalopods to global change
- 8 Global change and the fossil fish record: the relevance of systematics
- 9 Response of shallow water foraminiferal palaeocommunities to global and regional environmental change
- 10 Intrinsic and extrinsic controls on the diversification of the Bivalvia
- 11 Global events and biotic interaction as controls on the evolution of gastropods
- 12 Algal symbiosis, and the collapse and recovery of reef communities: Lazarus corals across the K–T boundary
- 13 Changes in the diversity, taxic composition and life-history patterns of echinoids over the past 145 million years
- 14 Origin of the modern bryozoan fauna
- 15 Angiosperm diversification and Cretaceous environmental change
- 16 Cenozoic evolution of modern plant communities and vegetation
- 17 Leaf physiognomy and climate change
- 18 Biotic response to Late Quaternary global change – the pollen record: a case study from the Upper Thames Valley, England
- 19 The Cretaceous and Cenozoic record of insects (Hexapoda) with regard to global change
- 20 The palaeoclimatological significance of Late Cenozoic Coleoptera: familiar species in very unfamiliar circumstances
- 21 Amphibians, reptiles and birds: a biogeographical review
- 22 Paleogene mammals: crises and ecological change
- 23 Response of Old World terrestrial vertebrate biotas to Neogene climate change
- 24 Mammalian response to global change in the later Quaternary of the British Isles
- 25 Human evolution: how an African primate became global
- 26 The biotic response to global change: a summary
- References
- Index
15 - Angiosperm diversification and Cretaceous environmental change
Published online by Cambridge University Press: 14 August 2009
- Frontmatter
- Contents
- List of contributors
- Preface
- 1 Introduction
- 2 The Cretaceous world
- 3 The Cenozoic world
- 4 Calcareous nannoplankton and global climate change
- 5 Phenotypic response of foraminifera to episodes of global environmental change
- 6 The response of planktonic foraminifera to the Late Pliocene intensification of Northern Hemisphere glaciation
- 7 The response of Cretaceous cephalopods to global change
- 8 Global change and the fossil fish record: the relevance of systematics
- 9 Response of shallow water foraminiferal palaeocommunities to global and regional environmental change
- 10 Intrinsic and extrinsic controls on the diversification of the Bivalvia
- 11 Global events and biotic interaction as controls on the evolution of gastropods
- 12 Algal symbiosis, and the collapse and recovery of reef communities: Lazarus corals across the K–T boundary
- 13 Changes in the diversity, taxic composition and life-history patterns of echinoids over the past 145 million years
- 14 Origin of the modern bryozoan fauna
- 15 Angiosperm diversification and Cretaceous environmental change
- 16 Cenozoic evolution of modern plant communities and vegetation
- 17 Leaf physiognomy and climate change
- 18 Biotic response to Late Quaternary global change – the pollen record: a case study from the Upper Thames Valley, England
- 19 The Cretaceous and Cenozoic record of insects (Hexapoda) with regard to global change
- 20 The palaeoclimatological significance of Late Cenozoic Coleoptera: familiar species in very unfamiliar circumstances
- 21 Amphibians, reptiles and birds: a biogeographical review
- 22 Paleogene mammals: crises and ecological change
- 23 Response of Old World terrestrial vertebrate biotas to Neogene climate change
- 24 Mammalian response to global change in the later Quaternary of the British Isles
- 25 Human evolution: how an African primate became global
- 26 The biotic response to global change: a summary
- References
- Index
Summary
INTRODUCTION
Flowering plants (angiosperms) comprise 250 000–300 000 living species and are more diverse than all other groups of extant plants combined. They dominate the vegetation over most of the Earth's land surface and therefore account for most of the primary productivity in terrestrial ecosystems. Despite their present-day importance, flowering plants were the last major group of land plants to appear in the fossil record. While all other major groups have an extensive fossil record that extends back to the Paleozoic or earliest Mesozoic, angiosperms have no well-established fossil record prior to the Cretaceous (Crane et al., 1995). The origin of flowering plants, and especially their rapid diversification during the Cretaceous and Tertiary, is therefore of great evolutionary interest and had profound consequences for the evolution of terrestrial ecosystems and the animals that inhabit them (Friis et al., 1987; Wing et al., 1992).
In this chapter we briefly introduce recent studies of angiosperm diversification, review the changing diversity of major plant groups through the Cretaceous, present new data on changing patterns of abundance, and briefly discuss the possible relationship between vegetational patterns and other aspects of Cretaceous global environmental change. While there is currently no clear evidence that the diversification of flowering plants was triggered by changes in the global environment, several patterns of vegetational change during the mid Cretaceous correlate broadly with major environmental perturbations including oceanic anoxia, increased tectonic activity and rapid sea floor spreading.
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- Biotic Response to Global ChangeThe Last 145 Million Years, pp. 207 - 222Publisher: Cambridge University PressPrint publication year: 2000
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