Difference between revisions of "Nutrients"

|Application=Global Environmental Outlook - GEO3 (2002) project; Global Environmental Outlook - GEO4 (2007) project; Millennium Ecosystem Assessment - MA project; OECD Environmental Outlook to 2030 (2008) project; OECD Environmental Outlook to 2050 (2012) project; Resource Efficiency project; Rethinking Biodiversity Strategies (2010) project; Roads from Rio+20 (2012) project; SSP project; The Protein Puzzle (2011) project;

|IMAGEComponent=Scenario drivers; Agricultural economy and forestry; Agricultural systems; Agriculture and land use; Aquatic biodiversity; Emissions; Land cover and use; Livestock;

|KeyReference=Bouwman et al., 2013a; Bouwman et al., 2009; Van Drecht et al., 2009; Morée et al., 2013;

|Reference=Bouwman et al., 2013ab; Galloway et al., 2004; Zhang et al., 2010;  Diaz and Rosenberg, 2008; UNEP, 2002; Rabalais, 2002;

|Description=Human activity has accelerated the Earth’s biogeochemical nitrogen (N) and phosphorus (P) cycles through increasing fertiliser use in agriculture ([[Bouwman et al., 2013ab]]). Increased use of N and P fertilisers has raised food production to support the rapidly growing world population, and increasing per capita consumption particularly of meat and milk ([[Galloway et al., 2004]]). Increased fertiliser use has contributed to ongoing increases in crop yields.

A side effect is that significant proportions of the mobilised N are lost through ambient emissions of ammonia (NH3), nitrous oxide (N2O) and nitric oxide (NO). Ammonia contributes to eutrophication and acidification when deposited on land. Nitric oxide plays a role in tropospheric ozone chemistry, and nitrous oxide is a potent greenhouse gas. Moreover, large proportions of mobilised N and P in watersheds enter the groundwater through leaching, and are released to surface waters through groundwater transport and surface runoff. Subsequently, nutrients in streams and rivers are transported to coastal marine systems, reduced by retention but augmented by releases from point sources, such as sewerage systems and industrial facilities.

This has resulted in negative impacts on human health and the environment, such as groundwater pollution, loss of habitat and biodiversity, an increases in the frequency and severity of harmful algal blooms, eutrophication, hypoxia and fish kills ([[Diaz and Rosenberg, 2008]]; [[Zhang et al., 2010]]). The harmful effects of eutrophication have spread rapidly around the world, with large-scale implications for biodiversity, water quality, fisheries and recreation, in both industrialised and developing regions ([[UNEP, 2002]]). Input of nutrients in freshwater and coastal marine ecosystems, also disturbs the stoichiometric balance of N, P and silica (Si) ([[Rabalais, 2002]]) affecting total plant production and the species composition in ecosystems.

To assess eutrophication as a consequence of increasing population, and economic and technological development, IMAGE 3.0 includes a nutrient model, which comprises three sub-models:

# Wastewater emissions  to generate nutrient flows in wastewater discharges (See figure on the right I);

# Soil nutrient budget to describe all input and output of N and P in soil compartments (See figure on the right II);

# Nutrient environmental fate to describe the fate of soil nutrient surpluses and wastewater nutrients in the aquatic environment, (See figure on the right III).