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
10 - Intrinsic and extrinsic controls on the diversification of the Bivalvia
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
At the present day the Class Bivalvia comprises some 8000 species, sub-divided into approximately 700 genera, 107 families, and 41 superfamilies (Morton, 1996, and references therein). It represents one of the most diverse invertebrate groups within the marine realm and is often portrayed as the end-product of a long-term, adaptive radiation (e.g. Stanley, 1977). Over the last 250 Ma, in particular, there has been a steady but inexorable rise in the number of bivalve taxa (Fig. 10.1), and today they have come to occupy a very broad spectrum of benthic habitats and trophic categories (e.g. Bottjer, 1985). This is what Morton (1996, p. 348) has referred to as the ‘expanding success of the Bivalvia’.
Although the possible effects of the ‘pull of the Recent’ cannot be ignored (Hallam & Miller, 1988), it would appear that there was a particularly steep rise in the number of bivalve taxa through the latest Mesozoic and Cenozoic eras (Fig. 10.1). Other benthic groups, such as the echinoids, gastropods, decapod crustaceans and fishes, show this pattern too (e.g. Vermeij, 1977), and it becomes a matter of some importance to determine why this should be so. Geologists are now almost certain that, over the greater part of the last 90 Ma, marine climates have been deteriorating (Pickering, this volume); glacial climates may now be traced back over 40 Ma in Antarctica (see below).
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- Biotic Response to Global ChangeThe Last 145 Million Years, pp. 135 - 148Publisher: Cambridge University PressPrint publication year: 2000
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