Book contents
- Frontmatter
- Dedication
- Epigraph
- Contents
- Foreword and Preface
- Preface
- Summary of the first global integrated marine assessment
- The context of the assessment
- Assessment of Major Ecosystem Services from the Marine Environment (Other than Provisioning Services)
- Chapter 3 Scientific Understanding of Ecosystem Services
- Chapter 4 The Ocean's Role in the Hydrological Cycle
- Chapter 5 Sea-Air Interactions
- Chapter 6 Primary Production, Cycling of Nutrients, Surface Layer and Plankton
- Chapter 7 Calcium Carbonate Production and Contribution to Coastal Sediments
- Chapter 8 Aesthetic, Cultural, Religious and Spiritual Ecosystem Services Derived from the Marine Environment
- Chapter 9 Conclusions on Major Ecosystem Services Other than Provisioning Services
- Assessment of the Cross-cutting Issues: Food Security and Food Safety
- Assessment of Other Human Activities and the Marine Environment
- Assessment of Marine Biological Diversity and Habitats
- Section A Overview of Marine Biological Diversity
- Chapter 36 Overview of Marine Biological Diversity
- Section B Marine Ecosystems, Species and Habitats Scientifically Identified as Threatened, Declining or Otherwise in need of Special Attention or Protection
- I Marine Species
- II Marine Ecosystems and Habitats
- Section C Environmental, economic and/or social aspects of the conservation of marine species and habitats and capacity-building needs
- Overall Assessment
- Annexes
- References
Chapter 7 - Calcium Carbonate Production and Contribution to Coastal Sediments
from Assessment of Major Ecosystem Services from the Marine Environment (Other than Provisioning Services)
Published online by Cambridge University Press: 18 May 2017
Edited by
Book contents
- Frontmatter
- Dedication
- Epigraph
- Contents
- Foreword and Preface
- Preface
- Summary of the first global integrated marine assessment
- The context of the assessment
- Assessment of Major Ecosystem Services from the Marine Environment (Other than Provisioning Services)
- Chapter 3 Scientific Understanding of Ecosystem Services
- Chapter 4 The Ocean's Role in the Hydrological Cycle
- Chapter 5 Sea-Air Interactions
- Chapter 6 Primary Production, Cycling of Nutrients, Surface Layer and Plankton
- Chapter 7 Calcium Carbonate Production and Contribution to Coastal Sediments
- Chapter 8 Aesthetic, Cultural, Religious and Spiritual Ecosystem Services Derived from the Marine Environment
- Chapter 9 Conclusions on Major Ecosystem Services Other than Provisioning Services
- Assessment of the Cross-cutting Issues: Food Security and Food Safety
- Assessment of Other Human Activities and the Marine Environment
- Assessment of Marine Biological Diversity and Habitats
- Section A Overview of Marine Biological Diversity
- Chapter 36 Overview of Marine Biological Diversity
- Section B Marine Ecosystems, Species and Habitats Scientifically Identified as Threatened, Declining or Otherwise in need of Special Attention or Protection
- I Marine Species
- II Marine Ecosystems and Habitats
- Section C Environmental, economic and/or social aspects of the conservation of marine species and habitats and capacity-building needs
- Overall Assessment
- Annexes
- References
Summary
Calcium carbonate production in coastal environments
Biological production of calcium carbonate in the oceans is an important process. Although carbonate is produced in the open ocean (pelagic, see Chapter 5), this chapter concentrates on production in coastal waters (neritic) because this contributes sediment to the coast through skeletal breakdown producing sand and gravel deposits on beaches, across continental shelves, and within reefs. Marine organisms with hard body parts precipitate calcium carbonate as the minerals calcite or aragonite. Corals, molluscs, foraminifera, bryozoans, red algae (for example the algal rims that characterize reef crests on Indo-Pacific reefs) are particularly productive, as well as some species of green algae (especially Halimeda). Upon death, these calcareous organisms break down by physical, chemical, and biological erosion processes through a series of discrete sediment sizes (Perry et al., 2011). Neritic carbonate production has been estimated to be approximately 2.5 Gt year-1(Milliman and Droxler, 1995; Heap et al., 2009). The greatest contributors are coral reefs that form complex structures covering a total area of more than 250,000 km2 (Spalding and Grenfell, 1997; Vecsei, 2004), but other organisms, such as oysters, may also form smaller reef structures.
Global climate change will affect carbonate production and breakdown in the ocean, which will have implications for coastal sediment budgets. Rising sea level will displace many beaches landwards (Nicholls et al., 2007). Low-lying reef islands called sand cays, formed over the past few millennia on the rim of atolls, are particularly vulnerable, together with the communities that live on them. Rising sea level can also result in further reef growth and sediment production where there are healthy coral reefs (Buddemeier and Hopley, 1988). In areas where corals have already been killed or damaged by human activities, however, reefs may not be able to keep pace with the rising sea level in which case wave energy will be able to propagate more freely across the reef crest thereby exposing shorelines to higher levels of wave energy (Storlazzi et al., 2011; see also Chapter 43).
Reefs have experienced episodes of coral bleaching and mortality in recent years caused by unusually warm waters. Increased carbon dioxide concentrations are also causing ocean waters to become more acidic, which may affect the biological production and supply of carbonate sand. Bleaching and acidification can reduce coral growth and limit the ability of reef-building corals and other organisms to produce calcium carbonate (Kroeker et al., 2010).
- Type
- Chapter
- Information
- The First Global Integrated Marine AssessmentWorld Ocean Assessment I, pp. 149 - 158Publisher: Cambridge University PressPrint publication year: 2017
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