The links between biodiversity and ecosystem services

Research output: Contributions to collected editions/worksContributions to collected editions/anthologiesResearchpeer-review

Standard

The links between biodiversity and ecosystem services. / Balvanera, Patricia; Quijas, Sandra; Martín-López, B. et al.
Routledge Handbook of Ecosystem Services. ed. / Marion Potschin; Roy Haines-Young; Robert Fish. London: Taylor & Francis, 2016. p. 85-104.

Research output: Contributions to collected editions/worksContributions to collected editions/anthologiesResearchpeer-review

Harvard

Balvanera, P, Quijas, S, Martín-López, B, Barrios, E, Dee, L, Isbell, F, Durance, I, White, P, Blanchard, R & de Groot, R 2016, The links between biodiversity and ecosystem services. in M Potschin, R Haines-Young & R Fish (eds), Routledge Handbook of Ecosystem Services. Taylor & Francis, London, pp. 85-104. https://doi.org/10.4324/9781315775302

APA

Balvanera, P., Quijas, S., Martín-López, B., Barrios, E., Dee, L., Isbell, F., Durance, I., White, P., Blanchard, R., & de Groot, R. (2016). The links between biodiversity and ecosystem services. In M. Potschin, R. Haines-Young, & R. Fish (Eds.), Routledge Handbook of Ecosystem Services (pp. 85-104). Taylor & Francis. https://doi.org/10.4324/9781315775302

Vancouver

Balvanera P, Quijas S, Martín-López B, Barrios E, Dee L, Isbell F et al. The links between biodiversity and ecosystem services. In Potschin M, Haines-Young R, Fish R, editors, Routledge Handbook of Ecosystem Services. London: Taylor & Francis. 2016. p. 85-104 doi: 10.4324/9781315775302

Bibtex

@inbook{546949ea0ea1445ea4bbdc99d0eb7ea1,
title = "The links between biodiversity and ecosystem services",
abstract = "Key concepts relevant to understanding the links between biodiversity and ecosystem services Different facets of the biodiversity link to ecosystem services Biodiversity broadly encompasses the number, abundances, functional variety, spatial distribu-tion, and interactions of genotypes, species, populations, communities, and ecosystems. What levels of organization or components of biodiversity are likely to be most strongly linked with ecosystem services? For plant-dependent services, the local number of functional groups and total number of species (richness) can offer a crude first-order prediction for several ecosystem processes, such as productivity, and services, such as forage production. For animal-dependent services, species number and composition in mammalian communities are associated with reg-ulation of infectious disease, although the direction of this effect (amplification or dilution of disease) depends on the types and relative abundance of different vector species in the commu-nity (Ostfeld and Keesing, 2012). The equity of the abundances (evenness) of individual species is also important in relation to biological invasions. For example, reducing evenness in plant species communities can decrease resistance to invasion by exotic plants and insect herbivores (Wilsey and Polley, 2002). Theory predicts that increasing horizontal diversity (numbers of species within trophic lev-els) tends to promote several ecosystem functions that feed into ecosystem services; however, increasing vertical diversity (numbers of trophic levels) does not necessarily do so (Loreau, 2010). For plant-dependent ecosystem services, the level of service delivery probably depends most on local plant diversity because plant species interact at a local spatial scale, but there is some evidence that ecosystem services could depend on plant diversity at larger spatial scales (beta or gamma diversity; Isbell et al., 2011). The different components of ecosystem services A critical issue in ecosystem service assessments is the scant knowledge on how ecosystem services and their components (i.e. supply, delivery, use demand, value and benefits) are produced and maintained, how they are affected by system changes, such as land use change, and how they depend on different levels of biodiversity. To improve this knowledge, we distinguish between ecological processes (called 'supporting services' in the Millennium Ecosystem Assessment; MA, 2005) and 'functions' that produce ecosystem services. Func-tions are intermediate products; they are necessary to the production of services but are not services themselves, i.e., not used or acknowledged directly by a beneficiary. These interme-diate products or processes often underpin or determine the potential service production or supply, which can benefit society. The delivery of a service arises from the interaction between its supply and the demand from stakeholders who benefit from it (Tallis et al., 2012). The benefit and value of a service reflect how people assign importance to the ser-vice, which can be evaluated in terms of market value or from a cultural perspective. For example, primary production (an ecosystem process) is needed to maintain abundance of fish population (the service supply), which can be harvested to provide food (delivery) and high nutritional value (benefit). As another example, nutrient cycling (process) is needed for water purification (supply) to provide clean water (delivery) for domestic use (benefit) (Raffaelli, 2016; Jax, 2016a).",
keywords = "Sustainability Science",
author = "Patricia Balvanera and Sandra Quijas and B. Mart{\'i}n-L{\'o}pez and Edmundo Barrios and Laura Dee and Forest Isbell and Isabelle Durance and Piran White and Ryan Blanchard and {de Groot}, Rudolf",
year = "2016",
doi = "10.4324/9781315775302",
language = "English",
isbn = "1138025089",
pages = "85--104",
editor = "Marion Potschin and Haines-Young, { Roy} and Fish, {Robert }",
booktitle = "Routledge Handbook of Ecosystem Services",
publisher = "Taylor & Francis",
address = "United States",

}

RIS

TY - CHAP

T1 - The links between biodiversity and ecosystem services

AU - Balvanera, Patricia

AU - Quijas, Sandra

AU - Martín-López, B.

AU - Barrios, Edmundo

AU - Dee, Laura

AU - Isbell, Forest

AU - Durance, Isabelle

AU - White, Piran

AU - Blanchard, Ryan

AU - de Groot, Rudolf

PY - 2016

Y1 - 2016

N2 - Key concepts relevant to understanding the links between biodiversity and ecosystem services Different facets of the biodiversity link to ecosystem services Biodiversity broadly encompasses the number, abundances, functional variety, spatial distribu-tion, and interactions of genotypes, species, populations, communities, and ecosystems. What levels of organization or components of biodiversity are likely to be most strongly linked with ecosystem services? For plant-dependent services, the local number of functional groups and total number of species (richness) can offer a crude first-order prediction for several ecosystem processes, such as productivity, and services, such as forage production. For animal-dependent services, species number and composition in mammalian communities are associated with reg-ulation of infectious disease, although the direction of this effect (amplification or dilution of disease) depends on the types and relative abundance of different vector species in the commu-nity (Ostfeld and Keesing, 2012). The equity of the abundances (evenness) of individual species is also important in relation to biological invasions. For example, reducing evenness in plant species communities can decrease resistance to invasion by exotic plants and insect herbivores (Wilsey and Polley, 2002). Theory predicts that increasing horizontal diversity (numbers of species within trophic lev-els) tends to promote several ecosystem functions that feed into ecosystem services; however, increasing vertical diversity (numbers of trophic levels) does not necessarily do so (Loreau, 2010). For plant-dependent ecosystem services, the level of service delivery probably depends most on local plant diversity because plant species interact at a local spatial scale, but there is some evidence that ecosystem services could depend on plant diversity at larger spatial scales (beta or gamma diversity; Isbell et al., 2011). The different components of ecosystem services A critical issue in ecosystem service assessments is the scant knowledge on how ecosystem services and their components (i.e. supply, delivery, use demand, value and benefits) are produced and maintained, how they are affected by system changes, such as land use change, and how they depend on different levels of biodiversity. To improve this knowledge, we distinguish between ecological processes (called 'supporting services' in the Millennium Ecosystem Assessment; MA, 2005) and 'functions' that produce ecosystem services. Func-tions are intermediate products; they are necessary to the production of services but are not services themselves, i.e., not used or acknowledged directly by a beneficiary. These interme-diate products or processes often underpin or determine the potential service production or supply, which can benefit society. The delivery of a service arises from the interaction between its supply and the demand from stakeholders who benefit from it (Tallis et al., 2012). The benefit and value of a service reflect how people assign importance to the ser-vice, which can be evaluated in terms of market value or from a cultural perspective. For example, primary production (an ecosystem process) is needed to maintain abundance of fish population (the service supply), which can be harvested to provide food (delivery) and high nutritional value (benefit). As another example, nutrient cycling (process) is needed for water purification (supply) to provide clean water (delivery) for domestic use (benefit) (Raffaelli, 2016; Jax, 2016a).

AB - Key concepts relevant to understanding the links between biodiversity and ecosystem services Different facets of the biodiversity link to ecosystem services Biodiversity broadly encompasses the number, abundances, functional variety, spatial distribu-tion, and interactions of genotypes, species, populations, communities, and ecosystems. What levels of organization or components of biodiversity are likely to be most strongly linked with ecosystem services? For plant-dependent services, the local number of functional groups and total number of species (richness) can offer a crude first-order prediction for several ecosystem processes, such as productivity, and services, such as forage production. For animal-dependent services, species number and composition in mammalian communities are associated with reg-ulation of infectious disease, although the direction of this effect (amplification or dilution of disease) depends on the types and relative abundance of different vector species in the commu-nity (Ostfeld and Keesing, 2012). The equity of the abundances (evenness) of individual species is also important in relation to biological invasions. For example, reducing evenness in plant species communities can decrease resistance to invasion by exotic plants and insect herbivores (Wilsey and Polley, 2002). Theory predicts that increasing horizontal diversity (numbers of species within trophic lev-els) tends to promote several ecosystem functions that feed into ecosystem services; however, increasing vertical diversity (numbers of trophic levels) does not necessarily do so (Loreau, 2010). For plant-dependent ecosystem services, the level of service delivery probably depends most on local plant diversity because plant species interact at a local spatial scale, but there is some evidence that ecosystem services could depend on plant diversity at larger spatial scales (beta or gamma diversity; Isbell et al., 2011). The different components of ecosystem services A critical issue in ecosystem service assessments is the scant knowledge on how ecosystem services and their components (i.e. supply, delivery, use demand, value and benefits) are produced and maintained, how they are affected by system changes, such as land use change, and how they depend on different levels of biodiversity. To improve this knowledge, we distinguish between ecological processes (called 'supporting services' in the Millennium Ecosystem Assessment; MA, 2005) and 'functions' that produce ecosystem services. Func-tions are intermediate products; they are necessary to the production of services but are not services themselves, i.e., not used or acknowledged directly by a beneficiary. These interme-diate products or processes often underpin or determine the potential service production or supply, which can benefit society. The delivery of a service arises from the interaction between its supply and the demand from stakeholders who benefit from it (Tallis et al., 2012). The benefit and value of a service reflect how people assign importance to the ser-vice, which can be evaluated in terms of market value or from a cultural perspective. For example, primary production (an ecosystem process) is needed to maintain abundance of fish population (the service supply), which can be harvested to provide food (delivery) and high nutritional value (benefit). As another example, nutrient cycling (process) is needed for water purification (supply) to provide clean water (delivery) for domestic use (benefit) (Raffaelli, 2016; Jax, 2016a).

KW - Sustainability Science

U2 - 10.4324/9781315775302

DO - 10.4324/9781315775302

M3 - Contributions to collected editions/anthologies

SN - 1138025089

SN - 978-1-138-02508-0

SP - 85

EP - 104

BT - Routledge Handbook of Ecosystem Services

A2 - Potschin, Marion

A2 - Haines-Young, Roy

A2 - Fish, Robert

PB - Taylor & Francis

CY - London

ER -