Book contents
- Frontmatter
- Dedication
- Contents
- List of contributors
- Foreword
- Acknowledgements
- 1 Introducing wood ants: evolution, phylogeny, identification and distribution
- 2 Wood ant reproductive biology and social systems
- 3 Population genetics of wood ants
- 4 Where and why? Wood ant population ecology
- 5 Colony and species recognition among the Formica ants
- 6 Interspecific competition and coexistence between wood ants
- 7 Wood ant foraging and mutualism with aphids
- 8 Wood ants and their interaction with other organisms
- 9 Contribution of wood ants to nutrient cycling and ecosystem function
- 10 Diversity, ecology and conservation of wood ants in North America
- 11 Sampling and monitoring wood ants
- 12 Threats, conservation and management
- 13 Future directions for wood ant ecology and conservation
- Index
- References
9 - Contribution of wood ants to nutrient cycling and ecosystem function
Published online by Cambridge University Press: 05 June 2016
Book contents
- Frontmatter
- Dedication
- Contents
- List of contributors
- Foreword
- Acknowledgements
- 1 Introducing wood ants: evolution, phylogeny, identification and distribution
- 2 Wood ant reproductive biology and social systems
- 3 Population genetics of wood ants
- 4 Where and why? Wood ant population ecology
- 5 Colony and species recognition among the Formica ants
- 6 Interspecific competition and coexistence between wood ants
- 7 Wood ant foraging and mutualism with aphids
- 8 Wood ants and their interaction with other organisms
- 9 Contribution of wood ants to nutrient cycling and ecosystem function
- 10 Diversity, ecology and conservation of wood ants in North America
- 11 Sampling and monitoring wood ants
- 12 Threats, conservation and management
- 13 Future directions for wood ant ecology and conservation
- Index
- References
Summary
Red wood ants (Formica rufa group) build large and long-lasting nest mounds. Due to their construction, nest mounds and especially their centres, provide a favourable microclimate for brood development (Coenen-Staβ 1980). However, constructing and maintaining the nest in addition to feeding the colony requires a considerable amount of energy and building material. The ‘central-place foraging’ strategy (Chapter 7) employed by red wood ants – retrieving food and plant material from the area surrounding the nest – means they influence not only the properties of their nests, but also those of the wider area.
Wood ants influence the functioning of forest ecosystems through altering food web structure (Chapter 8), soil properties, and nutrient transport and energy flow (Frouz and Jílková 2008). The vast accumulation of organic materials in the nest means that once the nest is no longer in use, nutrients are released during the decomposition process which is performed by microorganisms (Lenoir et al. 2001). These nutrients are then available for plant growth. This chapter addresses the effects of wood ants on nutrient flow and plant growth in forest ecosystems. Since these effects are associated with nest building and territorial activities, they can be divided into nest- and territory-related effects.
Nest-related effects
Foraging for food
Nest-related effects are connected with foraging, nest construction and the subsequent decomposition of organic materials. Decomposition in nests is enhanced because of the abundance of microorganisms and the favourable microclimate. Mineral nutrients are released from organic materials but predominantly remain in or near the ant nests, thus creating hot spots in nutrient-limited forest ecosystems. Wood ants feed on honeydew and solid insect prey; honeydew rarely forms less than two-thirds of the energy imported to F. rufa nests (Whittaker 1991). Ants may collect more than 80% of the excreted honeydew, which constitutes 62–94% of their diet and contains 15–20% sugars, a small percentage of amino acids and c. 70% water (Rosengren and Sundström 1991). Thus, approximately 13–16 kg of honeydew dry mass containing a significant amount of nutrients (Table 9.1) is transported annually into the average ant nest (Frouz et al. 1997; Jilková et al. 2012). Once transported into the ant nest, the honeydew is redistributed and used as a source of energy (Horstmann 1974).
- Type
- Chapter
- Information
- Wood Ant Ecology and Conservation , pp. 207 - 220Publisher: Cambridge University PressPrint publication year: 2016
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