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44845 | Excess fertilizer use: Which countries cause environmental damage by overapplying fertilizers? | untitled-reusable-block-285 | wp_block | publish | <!-- wp:paragraph --> <p>Fertilizers have brought the world massive socioeconomic and developmental benefits. They improve crop yields. This has two advantages. First, we can grow more food. Second, we need to use less land for farming, and therefore destroy fewer ecosystems in the process.</p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p>But alongside these environmental benefits, there are some downsides. Not all of the nutrients we apply – in fact, as we explore in a <strong><a href="https://ourworldindata.org/reducing-fertilizer-use">related article</a></strong>, less than half of it globally – is used by the crops.{ref}Lassaletta, L., Billen, G., Grizzetti, B., Anglade, J., & Garnier, J. (2014). <a href="https://iopscience.iop.org/article/10.1088/1748-9326/9/10/105011/meta">50 year trends in nitrogen use efficiency of world cropping systems: the relationship between yield and nitrogen input to cropland</a>. <em>Environmental Research Letters</em>, 9(10), 105011.{/ref} The rest runs off our farms into the natural environment: if this happens then it pollutes rivers and lakes; causes imbalances in ecosystems and affects biodiversity.</p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p>What is the global extent of fertilizer pollution? Which countries cause the most avoidable pollution?</p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p>We can measure this using a metric called “<em>excess</em> nutrients”. This metric shows us how much of the nutrients that farmers apply as fertilizer runs off into the natural environment.</p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p>In a paper published in <em>Science</em>, Paul West and his colleagues mapped the nutrient balance for nitrogen and phosphorus – the main nutrients we add to our crops – across the world.{ref}West, P. C., Gerber, J. S., Engstrom, P. M., Mueller, N. D., Brauman, K. A., Carlson, K. M., ... & Siebert, S. (2014). <a href="https://science.sciencemag.org/content/345/6194/325">Leverage points for improving global food security and the environment</a>. <em>Science</em>, 345(6194), 325-328.{/ref} They quantified the amount of nutrient <em>inputs</em> – this can come in the form of synthetic fertilizers, organic additions such as manure, or even biological fixation of nitrogen from legume plants – and the <em>output</em>, which is the amount of nitrogen or phosphorus that is stored in the crops that we harvest. </p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p>The difference between inputs and outputs is “excess”: nutrients that are not used by the crops and instead run-off into the natural environment.</p> <!-- /wp:paragraph --> <!-- wp:heading {"level":3} --> <h3>Nearly two-thirds of applied nitrogen is not used by our crops</h3> <!-- /wp:heading --> <!-- wp:columns {"className":"is-style-side-by-side"} --> <div class="wp-block-columns is-style-side-by-side"><!-- wp:column --> <div class="wp-block-column"><!-- wp:paragraph --> <p>This research finds that globally farmers apply around 115 million tonnes of nitrogen to our crops every year. Only around 35% of this is used by them, meaning 75 million tonnes of nitrogen runs off into our rivers, lakes and natural environments. This is our “excess nitrogen”. It is quite staggering that almost two-thirds of our applied nitrogen becomes an environmental pollutant.</p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p>Which countries create the most nitrogen pollution? The maps below show this from two perspectives. </p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p>First, as the excess nitrogen <em>per hectare of cropland</em>. Here we see large differences across the world. </p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p>Some countries actually produce ‘negative’ nitrogen pollution, they are shown in blue. This is known as nitrogen mining. This happens when countries <em>undersupply</em> nitrogen fertilizers, but continue to try to grow more and more crops. Crops then have to take nitrogen from the soil. Over time this depletes soils of their nutrients which will be bad for the productivity of these soils and crop production in the long-run.</p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p>Other countries massively <em>oversupply</em> nitrogen. These are the countries shown in the darker shades of red here. Countries such as Kuwait, Singapore, South Korea, Egypt, New Zealand, China, and Taiwan create more than 100 kilograms of excess nitrogen per hectare. For every hectare of cropland, they produce hundreds of kilograms of pollution.</p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p>The other map shows total nitrogen pollution – the sum of pollution generated in each country, rather than per hectare. This is given as each country’s share of the global total.</p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p>China generates the most nitrogen pollution, accounting for one-third of the global total. India produces almost one-fifth (18%); the USA produces 11%; followed by Pakistan and Brazil. </p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p>It’s not that surprising that the countries with the largest populations (and some of the largest land masses) create the most pollution. But as I explore in a <strong><a href="https://ourworldindata.org/reducing-fertilizer-use">related article</a></strong>, there are lots of opportunities to reduce fertilizer use (and pollution) without sacrificing crop yields.</p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p>Both of these metrics – the amount of excess nitrogen <em>per hectare</em>, and the total excess are important. Excess <em>per hectare</em> informs us of where nutrients are being used inefficiently; if this number is high then farmers are overapplying fertilizers and organic nutrients. But <em>total</em> excess is also important because it informs us of where we’re likely to have hotspots of water and ecosystem pollution. We need to be aware of regions with lots of farmland and excess nutrients because surrounding rivers and lakes are at high risk of becoming polluted.</p> <!-- /wp:paragraph --></div> <!-- /wp:column --> <!-- wp:column --> <div class="wp-block-column"></div> <!-- /wp:column --></div> <!-- /wp:columns --> <!-- wp:columns {"className":"is-style-side-by-side"} --> <div class="wp-block-columns is-style-side-by-side"><!-- wp:column --> <div class="wp-block-column"><!-- wp:html --> <iframe src="https://ourworldindata.org/grapher/excess-nitrogen-per-hectare?country=CHN~IND~USA~GBR~BRA~JPN~SWE~NOR" loading="lazy" style="width: 100%; height: 600px; border: 0px none;"></iframe> <!-- /wp:html --> <!-- wp:heading {"level":5} --> <h5>Related chart</h5> <!-- /wp:heading --> <!-- wp:owid/prominent-link {"title":"Excess nitrogen from croplands (total in tonnes per year)","linkUrl":"https://ourworldindata.org/grapher/excess-nitrogen","className":"is-style-thin"} /--></div> <!-- /wp:column --> <!-- wp:column --> <div class="wp-block-column"><!-- wp:html --> <iframe src="https://ourworldindata.org/grapher/share-global-excess-nitrogen?country=CHN~IND~USA~GBR~MEX~ZAF~BRA" loading="lazy" style="width: 100%; height: 600px; border: 0px none;"></iframe> <!-- /wp:html --></div> <!-- /wp:column --></div> <!-- /wp:columns --> <!-- wp:heading {"level":3} --> <h3>More than half of applied phosphorous is lost to the environment</h3> <!-- /wp:heading --> <!-- wp:columns {"className":"is-style-side-by-side"} --> <div class="wp-block-columns is-style-side-by-side"><!-- wp:column --> <div class="wp-block-column"><!-- wp:paragraph --> <p>The other main nutrient we add to our crops via fertilizers is phosphorous. </p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p>Globally farmers apply around 25 million tonnes every year. 14 million tonnes are not used by the crops and become a pollutant. That means that more than half goes to waste.</p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p>Just as we looked at with nitrogen, we can see which countries produce the most excess phosphorous; first per hectare, then as the total per year. This is shown in the maps below.</p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p>Most of the countries that overapply nitrogen are the same ones that also overapply phosphorous. Singapore, New Zealand, Japan, South Korea, and Belgium, are all near the top of the list.</p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p>Unsurprisingly, given their population size and land mass, the largest polluters are similar to nitrogen. China tops the list, producing one-third of the world’s excess phosphorous. This is followed by India at one-fifth; Brazil at 7%; United States at 6%; and Pakistan at 3%.</p> <!-- /wp:paragraph --></div> <!-- /wp:column --> <!-- wp:column --> <div class="wp-block-column"></div> <!-- /wp:column --></div> <!-- /wp:columns --> <!-- wp:columns {"className":"is-style-side-by-side"} --> <div class="wp-block-columns is-style-side-by-side"><!-- wp:column --> <div class="wp-block-column"><!-- wp:html --> <iframe src="https://ourworldindata.org/grapher/excess-phosphorous-per-hectare?country=CHN~IND~USA~GBR~BRA~PAK~MEX~AUS" loading="lazy" style="width: 100%; height: 600px; border: 0px none;"></iframe> <!-- /wp:html --> <!-- wp:heading {"level":5} --> <h5>Related chart</h5> <!-- /wp:heading --> <!-- wp:owid/prominent-link {"title":"Excess phosphorous from croplands (total in tonnes per year)","linkUrl":"https://ourworldindata.org/grapher/excess-phosphorous","className":"is-style-thin"} /--></div> <!-- /wp:column --> <!-- wp:column --> <div class="wp-block-column"><!-- wp:html --> <iframe src="https://ourworldindata.org/grapher/share-global-excess-phosphorous?country=PRT~ESP~CHN~IND~USA~BRA~PAK" loading="lazy" style="width: 100%; height: 600px; border: 0px none;"></iframe> <!-- /wp:html --></div> <!-- /wp:column --></div> <!-- /wp:columns --> <!-- wp:heading {"level":3} --> <h3>Some countries could use more fertilizer; some could use less</h3> <!-- /wp:heading --> <!-- wp:columns --> <div class="wp-block-columns"><!-- wp:column --> <div class="wp-block-column"><!-- wp:paragraph --> <p>Many countries – particularly poorer countries across Sub-Saharan Africa – do not use enough fertilizer. Their crop yields suffer as a result. This is bad for farmers; food security; and the environment because it means they need to use more land for agriculture. As I covered in my <a href="https://ourworldindata.org/yields-habitat-loss"><strong>recent article</strong></a>, Sub-Saharan Africa is projected to be the hotspot of habitat loss in the coming decades as a result of expanding croplands. Thousands of mammals, birds and amphibian species are at risk. The good news is that if we can improve crop yields, we can prevent almost all of this. Fertilizers will play an important role in achieving this.</p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p>At the other end of the spectrum, some countries use too much. They could use much less – and produce much less pollution – without it affecting crop yields. Getting this balance right would bring a range of socioeconomic and environmental benefits. In a <strong><a href="https://ourworldindata.org/reducing-fertilizer-use">related article</a></strong> we look at this trade-off in more detail, and explore the possible solutions for reducing nutrient pollution.</p> <!-- /wp:paragraph --></div> <!-- /wp:column --> <!-- wp:column --> <div class="wp-block-column"></div> <!-- /wp:column --></div> <!-- /wp:columns --> | { "id": "wp-44845", "slug": "untitled-reusable-block-285", "content": { "toc": [], "body": [ { "type": "text", "value": [ { "text": "Fertilizers have brought the world massive socioeconomic and developmental benefits. They improve crop yields. This has two advantages. First, we can grow more food. Second, we need to use less land for farming, and therefore destroy fewer ecosystems in the process.", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "But alongside these environmental benefits, there are some downsides. Not all of the nutrients we apply \u2013 in fact, as we explore in a ", "spanType": "span-simple-text" }, { "children": [ { "url": "https://ourworldindata.org/reducing-fertilizer-use", "children": [ { "text": "related article", "spanType": "span-simple-text" } ], "spanType": "span-link" } ], "spanType": "span-bold" }, { "text": ", less than half of it globally \u2013 is used by the crops.{ref}Lassaletta, L., Billen, G., Grizzetti, B., Anglade, J., & Garnier, J. (2014). ", "spanType": "span-simple-text" }, { "url": "https://iopscience.iop.org/article/10.1088/1748-9326/9/10/105011/meta", "children": [ { "text": "50 year trends in nitrogen use efficiency of world cropping systems: the relationship between yield and nitrogen input to cropland", "spanType": "span-simple-text" } ], "spanType": "span-link" }, { "text": ". ", "spanType": "span-simple-text" }, { "children": [ { "text": "Environmental Research Letters", "spanType": "span-simple-text" } ], "spanType": "span-italic" }, { "text": ", 9(10), 105011.{/ref} The rest runs off our farms into the natural environment: if this happens then it pollutes rivers and lakes; causes imbalances in ecosystems and affects biodiversity.", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "What is the global extent of fertilizer pollution? Which countries cause the most avoidable pollution?", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "We can measure this using a metric called \u201c", "spanType": "span-simple-text" }, { "children": [ { "text": "excess", "spanType": "span-simple-text" } ], "spanType": "span-italic" }, { "text": " nutrients\u201d. This metric shows us how much of the nutrients that farmers apply as fertilizer runs off into the natural environment.", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "In a paper published in ", "spanType": "span-simple-text" }, { "children": [ { "text": "Science", "spanType": "span-simple-text" } ], "spanType": "span-italic" }, { "text": ", Paul West and his colleagues mapped the nutrient balance for nitrogen and phosphorus \u2013 the main nutrients we add to our crops \u2013 across the world.{ref}West, P. C., Gerber, J. S., Engstrom, P. M., Mueller, N. D., Brauman, K. A., Carlson, K. M., ... & Siebert, S. (2014). ", "spanType": "span-simple-text" }, { "url": "https://science.sciencemag.org/content/345/6194/325", "children": [ { "text": "Leverage points for improving global food security and the environment", "spanType": "span-simple-text" } ], "spanType": "span-link" }, { "text": ". ", "spanType": "span-simple-text" }, { "children": [ { "text": "Science", "spanType": "span-simple-text" } ], "spanType": "span-italic" }, { "text": ", 345(6194), 325-328.{/ref} They quantified the amount of nutrient ", "spanType": "span-simple-text" }, { "children": [ { "text": "inputs", "spanType": "span-simple-text" } ], "spanType": "span-italic" }, { "text": " \u2013 this can come in the form of synthetic fertilizers, organic additions such as manure, or even biological fixation of nitrogen from legume plants \u2013 and the ", "spanType": "span-simple-text" }, { "children": [ { "text": "output", "spanType": "span-simple-text" } ], "spanType": "span-italic" }, { "text": ", which is the amount of nitrogen or phosphorus that is stored in the crops that we harvest.\u00a0", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "The difference between inputs and outputs is \u201cexcess\u201d: nutrients that are not used by the crops and instead run-off into the natural environment.", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "text": [ { "text": "Nearly two-thirds of applied nitrogen is not used by our crops", "spanType": "span-simple-text" } ], "type": "heading", "level": 2, "parseErrors": [] }, { "type": "text", "value": [ { "text": "This research finds that globally farmers apply around 115 million tonnes of nitrogen to our crops every year. Only around 35% of this is used by them, meaning 75 million tonnes of nitrogen runs off into our rivers, lakes and natural environments. This is our \u201cexcess nitrogen\u201d. It is quite staggering that almost two-thirds of our applied nitrogen becomes an environmental pollutant.", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "Which countries create the most nitrogen pollution? The maps below show this from two perspectives.\u00a0", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "First, as the excess nitrogen ", "spanType": "span-simple-text" }, { "children": [ { "text": "per hectare of cropland", "spanType": "span-simple-text" } ], "spanType": "span-italic" }, { "text": ". Here we see large differences across the world.\u00a0", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "Some countries actually produce \u2018negative\u2019 nitrogen pollution, they are shown in blue. This is known as nitrogen mining. This happens when countries ", "spanType": "span-simple-text" }, { "children": [ { "text": "undersupply", "spanType": "span-simple-text" } ], "spanType": "span-italic" }, { "text": " nitrogen fertilizers, but continue to try to grow more and more crops. Crops then have to take nitrogen from the soil. Over time this depletes soils of their nutrients which will be bad for the productivity of these soils and crop production in the long-run.", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "Other countries massively ", "spanType": "span-simple-text" }, { "children": [ { "text": "oversupply", "spanType": "span-simple-text" } ], "spanType": "span-italic" }, { "text": " nitrogen. These are the countries shown in the darker shades of red here. Countries such as Kuwait, Singapore, South Korea, Egypt, New Zealand, China, and Taiwan create more than 100 kilograms of excess nitrogen per hectare. For every hectare of cropland, they produce hundreds of kilograms of pollution.", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "The other map shows total nitrogen pollution \u2013 the sum of pollution generated in each country, rather than per hectare. This is given as each country\u2019s share of the global total.", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "China generates the most nitrogen pollution, accounting for one-third of the global total. India produces almost one-fifth (18%); the USA produces 11%; followed by Pakistan and Brazil.\u00a0", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "It\u2019s not that surprising that the countries with the largest populations (and some of the largest land masses) create the most pollution. But as I explore in a ", "spanType": "span-simple-text" }, { "children": [ { "url": "https://ourworldindata.org/reducing-fertilizer-use", "children": [ { "text": "related article", "spanType": "span-simple-text" } ], "spanType": "span-link" } ], "spanType": "span-bold" }, { "text": ", there are lots of opportunities to reduce fertilizer use (and pollution) without sacrificing crop yields.", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "Both of these metrics \u2013 the amount of excess nitrogen ", "spanType": "span-simple-text" }, { "children": [ { "text": "per hectare", "spanType": "span-simple-text" } ], "spanType": "span-italic" }, { "text": ", and the total excess are important. Excess ", "spanType": "span-simple-text" }, { "children": [ { "text": "per hectare", "spanType": "span-simple-text" } ], "spanType": "span-italic" }, { "text": " informs us of where nutrients are being used inefficiently; if this number is high then farmers are overapplying fertilizers and organic nutrients. But ", "spanType": "span-simple-text" }, { "children": [ { "text": "total", "spanType": "span-simple-text" } ], "spanType": "span-italic" }, { "text": " excess is also important because it informs us of where we\u2019re likely to have hotspots of water and ecosystem pollution. We need to be aware of regions with lots of farmland and excess nutrients because surrounding rivers and lakes are at high risk of becoming polluted.", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "left": [ { "url": "https://ourworldindata.org/grapher/excess-nitrogen-per-hectare?country=CHN~IND~USA~GBR~BRA~JPN~SWE~NOR", "type": "chart", "parseErrors": [] }, { "text": [ { "text": "Related chart", "spanType": "span-simple-text" } ], "type": "heading", "level": 5, "parseErrors": [] }, { "url": "https://ourworldindata.org/grapher/excess-nitrogen", "type": "prominent-link", "title": "Excess nitrogen from croplands (total in tonnes per year)", "description": "", "parseErrors": [] } ], "type": "sticky-right", "right": [ { "url": "https://ourworldindata.org/grapher/share-global-excess-nitrogen?country=CHN~IND~USA~GBR~MEX~ZAF~BRA", "type": "chart", "parseErrors": [] } ], "parseErrors": [] }, { "text": [ { "text": "More than half of applied phosphorous is lost to the environment", "spanType": "span-simple-text" } ], "type": "heading", "level": 2, "parseErrors": [] }, { "type": "text", "value": [ { "text": "The other main nutrient we add to our crops via fertilizers is phosphorous.\u00a0", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "Globally farmers apply around 25 million tonnes every year. 14 million tonnes are not used by the crops and become a pollutant. That means that more than half goes to waste.", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "Just as we looked at with nitrogen, we can see which countries produce the most excess phosphorous; first per hectare, then as the total per year. This is shown in the maps below.", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "Most of the countries that overapply nitrogen are the same ones that also overapply phosphorous. Singapore, New Zealand, Japan, South Korea, and Belgium, are all near the top of the list.", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "Unsurprisingly, given their population size and land mass, the largest polluters are similar to nitrogen. China tops the list, producing one-third of the world\u2019s excess phosphorous. 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Their crop yields suffer as a result. This is bad for farmers; food security; and the environment because it means they need to use more land for agriculture. As I covered in my ", "spanType": "span-simple-text" }, { "url": "https://ourworldindata.org/yields-habitat-loss", "children": [ { "children": [ { "text": "recent article", "spanType": "span-simple-text" } ], "spanType": "span-bold" } ], "spanType": "span-link" }, { "text": ", Sub-Saharan Africa is projected to be the hotspot of habitat loss in the coming decades as a result of expanding croplands. Thousands of mammals, birds and amphibian species are at risk. The good news is that if we can improve crop yields, we can prevent almost all of this. Fertilizers will play an important role in achieving this.", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "At the other end of the spectrum, some countries use too much. They could use much less \u2013 and produce much less pollution \u2013 without it affecting crop yields. Getting this balance right would bring a range of socioeconomic and environmental benefits. In a ", "spanType": "span-simple-text" }, { "children": [ { "url": "https://ourworldindata.org/reducing-fertilizer-use", "children": [ { "text": "related article", "spanType": "span-simple-text" } ], "spanType": "span-link" } ], "spanType": "span-bold" }, { "text": " we look at this trade-off in more detail, and explore the possible solutions for reducing nutrient pollution.", "spanType": "span-simple-text" } ], "parseErrors": [] } ], "type": "article", "title": "Excess fertilizer use: Which countries cause environmental damage by overapplying fertilizers?", "authors": [ null ], "dateline": "September 7, 2021", "sidebar-toc": false, "featured-image": "" }, "createdAt": "2021-09-07T12:30:21.000Z", "published": false, "updatedAt": "2021-11-15T16:32:09.000Z", "revisionId": null, "publishedAt": "2021-09-07T11:30:08.000Z", "relatedCharts": [], "publicationContext": "listed" } |
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2021-09-07 11:30:08 | 2024-02-16 14:23:02 | [ null ] |
2021-09-07 12:30:21 | 2021-11-15 16:32:09 | {} |
Fertilizers have brought the world massive socioeconomic and developmental benefits. They improve crop yields. This has two advantages. First, we can grow more food. Second, we need to use less land for farming, and therefore destroy fewer ecosystems in the process. But alongside these environmental benefits, there are some downsides. Not all of the nutrients we apply – in fact, as we explore in a **[related article](https://ourworldindata.org/reducing-fertilizer-use)**, less than half of it globally – is used by the crops.{ref}Lassaletta, L., Billen, G., Grizzetti, B., Anglade, J., & Garnier, J. (2014). [50 year trends in nitrogen use efficiency of world cropping systems: the relationship between yield and nitrogen input to cropland](https://iopscience.iop.org/article/10.1088/1748-9326/9/10/105011/meta). _Environmental Research Letters_, 9(10), 105011.{/ref} The rest runs off our farms into the natural environment: if this happens then it pollutes rivers and lakes; causes imbalances in ecosystems and affects biodiversity. What is the global extent of fertilizer pollution? Which countries cause the most avoidable pollution? We can measure this using a metric called “_excess_ nutrients”. This metric shows us how much of the nutrients that farmers apply as fertilizer runs off into the natural environment. In a paper published in _Science_, Paul West and his colleagues mapped the nutrient balance for nitrogen and phosphorus – the main nutrients we add to our crops – across the world.{ref}West, P. C., Gerber, J. S., Engstrom, P. M., Mueller, N. D., Brauman, K. A., Carlson, K. M., ... & Siebert, S. (2014). [Leverage points for improving global food security and the environment](https://science.sciencemag.org/content/345/6194/325). _Science_, 345(6194), 325-328.{/ref} They quantified the amount of nutrient _inputs_ – this can come in the form of synthetic fertilizers, organic additions such as manure, or even biological fixation of nitrogen from legume plants – and the _output_, which is the amount of nitrogen or phosphorus that is stored in the crops that we harvest. The difference between inputs and outputs is “excess”: nutrients that are not used by the crops and instead run-off into the natural environment. ## Nearly two-thirds of applied nitrogen is not used by our crops This research finds that globally farmers apply around 115 million tonnes of nitrogen to our crops every year. Only around 35% of this is used by them, meaning 75 million tonnes of nitrogen runs off into our rivers, lakes and natural environments. This is our “excess nitrogen”. It is quite staggering that almost two-thirds of our applied nitrogen becomes an environmental pollutant. Which countries create the most nitrogen pollution? The maps below show this from two perspectives. First, as the excess nitrogen _per hectare of cropland_. Here we see large differences across the world. Some countries actually produce ‘negative’ nitrogen pollution, they are shown in blue. This is known as nitrogen mining. This happens when countries _undersupply_ nitrogen fertilizers, but continue to try to grow more and more crops. Crops then have to take nitrogen from the soil. Over time this depletes soils of their nutrients which will be bad for the productivity of these soils and crop production in the long-run. Other countries massively _oversupply_ nitrogen. These are the countries shown in the darker shades of red here. Countries such as Kuwait, Singapore, South Korea, Egypt, New Zealand, China, and Taiwan create more than 100 kilograms of excess nitrogen per hectare. For every hectare of cropland, they produce hundreds of kilograms of pollution. The other map shows total nitrogen pollution – the sum of pollution generated in each country, rather than per hectare. This is given as each country’s share of the global total. China generates the most nitrogen pollution, accounting for one-third of the global total. India produces almost one-fifth (18%); the USA produces 11%; followed by Pakistan and Brazil. It’s not that surprising that the countries with the largest populations (and some of the largest land masses) create the most pollution. But as I explore in a **[related article](https://ourworldindata.org/reducing-fertilizer-use)**, there are lots of opportunities to reduce fertilizer use (and pollution) without sacrificing crop yields. Both of these metrics – the amount of excess nitrogen _per hectare_, and the total excess are important. Excess _per hectare_ informs us of where nutrients are being used inefficiently; if this number is high then farmers are overapplying fertilizers and organic nutrients. But _total_ excess is also important because it informs us of where we’re likely to have hotspots of water and ecosystem pollution. We need to be aware of regions with lots of farmland and excess nutrients because surrounding rivers and lakes are at high risk of becoming polluted. <Chart url="https://ourworldindata.org/grapher/excess-nitrogen-per-hectare?country=CHN~IND~USA~GBR~BRA~JPN~SWE~NOR"/> ##### Related chart ### Excess nitrogen from croplands (total in tonnes per year) https://ourworldindata.org/grapher/excess-nitrogen <Chart url="https://ourworldindata.org/grapher/share-global-excess-nitrogen?country=CHN~IND~USA~GBR~MEX~ZAF~BRA"/> ## More than half of applied phosphorous is lost to the environment The other main nutrient we add to our crops via fertilizers is phosphorous. Globally farmers apply around 25 million tonnes every year. 14 million tonnes are not used by the crops and become a pollutant. That means that more than half goes to waste. Just as we looked at with nitrogen, we can see which countries produce the most excess phosphorous; first per hectare, then as the total per year. This is shown in the maps below. Most of the countries that overapply nitrogen are the same ones that also overapply phosphorous. Singapore, New Zealand, Japan, South Korea, and Belgium, are all near the top of the list. Unsurprisingly, given their population size and land mass, the largest polluters are similar to nitrogen. China tops the list, producing one-third of the world’s excess phosphorous. This is followed by India at one-fifth; Brazil at 7%; United States at 6%; and Pakistan at 3%. <Chart url="https://ourworldindata.org/grapher/excess-phosphorous-per-hectare?country=CHN~IND~USA~GBR~BRA~PAK~MEX~AUS"/> ##### Related chart ### Excess phosphorous from croplands (total in tonnes per year) https://ourworldindata.org/grapher/excess-phosphorous <Chart url="https://ourworldindata.org/grapher/share-global-excess-phosphorous?country=PRT~ESP~CHN~IND~USA~BRA~PAK"/> ## Some countries could use more fertilizer; some could use less Many countries – particularly poorer countries across Sub-Saharan Africa – do not use enough fertilizer. Their crop yields suffer as a result. This is bad for farmers; food security; and the environment because it means they need to use more land for agriculture. As I covered in my [**recent article**](https://ourworldindata.org/yields-habitat-loss), Sub-Saharan Africa is projected to be the hotspot of habitat loss in the coming decades as a result of expanding croplands. Thousands of mammals, birds and amphibian species are at risk. The good news is that if we can improve crop yields, we can prevent almost all of this. Fertilizers will play an important role in achieving this. At the other end of the spectrum, some countries use too much. They could use much less – and produce much less pollution – without it affecting crop yields. Getting this balance right would bring a range of socioeconomic and environmental benefits. In a **[related article](https://ourworldindata.org/reducing-fertilizer-use)** we look at this trade-off in more detail, and explore the possible solutions for reducing nutrient pollution. | { "data": { "wpBlock": { "content": "\n<p>Fertilizers have brought the world massive socioeconomic and developmental benefits. They improve crop yields. This has two advantages. First, we can grow more food. Second, we need to use less land for farming, and therefore destroy fewer ecosystems in the process.</p>\n\n\n\n<p>But alongside these environmental benefits, there are some downsides. Not all of the nutrients we apply \u2013 in fact, as we explore in a <strong><a href=\"https://ourworldindata.org/reducing-fertilizer-use\">related article</a></strong>, less than half of it globally \u2013 is used by the crops.{ref}Lassaletta, L., Billen, G., Grizzetti, B., Anglade, J., & Garnier, J. (2014). <a href=\"https://iopscience.iop.org/article/10.1088/1748-9326/9/10/105011/meta\">50 year trends in nitrogen use efficiency of world cropping systems: the relationship between yield and nitrogen input to cropland</a>. <em>Environmental Research Letters</em>, 9(10), 105011.{/ref} The rest runs off our farms into the natural environment: if this happens then it pollutes rivers and lakes; causes imbalances in ecosystems and affects biodiversity.</p>\n\n\n\n<p>What is the global extent of fertilizer pollution? Which countries cause the most avoidable pollution?</p>\n\n\n\n<p>We can measure this using a metric called \u201c<em>excess</em> nutrients\u201d. This metric shows us how much of the nutrients that farmers apply as fertilizer runs off into the natural environment.</p>\n\n\n\n<p>In a paper published in <em>Science</em>, Paul West and his colleagues mapped the nutrient balance for nitrogen and phosphorus \u2013 the main nutrients we add to our crops \u2013 across the world.{ref}West, P. C., Gerber, J. S., Engstrom, P. M., Mueller, N. D., Brauman, K. A., Carlson, K. M., … & Siebert, S. (2014). <a href=\"https://science.sciencemag.org/content/345/6194/325\">Leverage points for improving global food security and the environment</a>. <em>Science</em>, 345(6194), 325-328.{/ref} They quantified the amount of nutrient <em>inputs</em> \u2013 this can come in the form of synthetic fertilizers, organic additions such as manure, or even biological fixation of nitrogen from legume plants \u2013 and the <em>output</em>, which is the amount of nitrogen or phosphorus that is stored in the crops that we harvest. </p>\n\n\n\n<p>The difference between inputs and outputs is \u201cexcess\u201d: nutrients that are not used by the crops and instead run-off into the natural environment.</p>\n\n\n\n<h3>Nearly two-thirds of applied nitrogen is not used by our crops</h3>\n\n\n\n<div class=\"wp-block-columns is-style-side-by-side\">\n<div class=\"wp-block-column\">\n<p>This research finds that globally farmers apply around 115 million tonnes of nitrogen to our crops every year. Only around 35% of this is used by them, meaning 75 million tonnes of nitrogen runs off into our rivers, lakes and natural environments. This is our \u201cexcess nitrogen\u201d. It is quite staggering that almost two-thirds of our applied nitrogen becomes an environmental pollutant.</p>\n\n\n\n<p>Which countries create the most nitrogen pollution? The maps below show this from two perspectives. </p>\n\n\n\n<p>First, as the excess nitrogen <em>per hectare of cropland</em>. Here we see large differences across the world. </p>\n\n\n\n<p>Some countries actually produce \u2018negative\u2019 nitrogen pollution, they are shown in blue. This is known as nitrogen mining. This happens when countries <em>undersupply</em> nitrogen fertilizers, but continue to try to grow more and more crops. Crops then have to take nitrogen from the soil. Over time this depletes soils of their nutrients which will be bad for the productivity of these soils and crop production in the long-run.</p>\n\n\n\n<p>Other countries massively <em>oversupply</em> nitrogen. These are the countries shown in the darker shades of red here. Countries such as Kuwait, Singapore, South Korea, Egypt, New Zealand, China, and Taiwan create more than 100 kilograms of excess nitrogen per hectare. For every hectare of cropland, they produce hundreds of kilograms of pollution.</p>\n\n\n\n<p>The other map shows total nitrogen pollution \u2013 the sum of pollution generated in each country, rather than per hectare. This is given as each country\u2019s share of the global total.</p>\n\n\n\n<p>China generates the most nitrogen pollution, accounting for one-third of the global total. India produces almost one-fifth (18%); the USA produces 11%; followed by Pakistan and Brazil. </p>\n\n\n\n<p>It\u2019s not that surprising that the countries with the largest populations (and some of the largest land masses) create the most pollution. But as I explore in a <strong><a href=\"https://ourworldindata.org/reducing-fertilizer-use\">related article</a></strong>, there are lots of opportunities to reduce fertilizer use (and pollution) without sacrificing crop yields.</p>\n\n\n\n<p>Both of these metrics \u2013 the amount of excess nitrogen <em>per hectare</em>, and the total excess are important. Excess <em>per hectare</em> informs us of where nutrients are being used inefficiently; if this number is high then farmers are overapplying fertilizers and organic nutrients. But <em>total</em> excess is also important because it informs us of where we\u2019re likely to have hotspots of water and ecosystem pollution. We need to be aware of regions with lots of farmland and excess nutrients because surrounding rivers and lakes are at high risk of becoming polluted.</p>\n</div>\n\n\n\n<div class=\"wp-block-column\"></div>\n</div>\n\n\n\n<div class=\"wp-block-columns is-style-side-by-side\">\n<div class=\"wp-block-column\">\n<iframe src=\"https://ourworldindata.org/grapher/excess-nitrogen-per-hectare?country=CHN~IND~USA~GBR~BRA~JPN~SWE~NOR\" loading=\"lazy\" style=\"width: 100%; height: 600px; border: 0px none;\"></iframe>\n\n\n\n<h5>Related chart</h5>\n\n\n <block type=\"prominent-link\" style=\"is-style-thin\">\n <link-url>https://ourworldindata.org/grapher/excess-nitrogen</link-url>\n <title>Excess nitrogen from croplands (total in tonnes per year)</title>\n <content></content>\n <figure></figure>\n </block></div>\n\n\n\n<div class=\"wp-block-column\">\n<iframe src=\"https://ourworldindata.org/grapher/share-global-excess-nitrogen?country=CHN~IND~USA~GBR~MEX~ZAF~BRA\" loading=\"lazy\" style=\"width: 100%; height: 600px; border: 0px none;\"></iframe>\n</div>\n</div>\n\n\n\n<h3>More than half of applied phosphorous is lost to the environment</h3>\n\n\n\n<div class=\"wp-block-columns is-style-side-by-side\">\n<div class=\"wp-block-column\">\n<p>The other main nutrient we add to our crops via fertilizers is phosphorous. </p>\n\n\n\n<p>Globally farmers apply around 25 million tonnes every year. 14 million tonnes are not used by the crops and become a pollutant. That means that more than half goes to waste.</p>\n\n\n\n<p>Just as we looked at with nitrogen, we can see which countries produce the most excess phosphorous; first per hectare, then as the total per year. This is shown in the maps below.</p>\n\n\n\n<p>Most of the countries that overapply nitrogen are the same ones that also overapply phosphorous. Singapore, New Zealand, Japan, South Korea, and Belgium, are all near the top of the list.</p>\n\n\n\n<p>Unsurprisingly, given their population size and land mass, the largest polluters are similar to nitrogen. China tops the list, producing one-third of the world\u2019s excess phosphorous. This is followed by India at one-fifth; Brazil at 7%; United States at 6%; and Pakistan at 3%.</p>\n</div>\n\n\n\n<div class=\"wp-block-column\"></div>\n</div>\n\n\n\n<div class=\"wp-block-columns is-style-side-by-side\">\n<div class=\"wp-block-column\">\n<iframe src=\"https://ourworldindata.org/grapher/excess-phosphorous-per-hectare?country=CHN~IND~USA~GBR~BRA~PAK~MEX~AUS\" loading=\"lazy\" style=\"width: 100%; height: 600px; border: 0px none;\"></iframe>\n\n\n\n<h5>Related chart</h5>\n\n\n <block type=\"prominent-link\" style=\"is-style-thin\">\n <link-url>https://ourworldindata.org/grapher/excess-phosphorous</link-url>\n <title>Excess phosphorous from croplands (total in tonnes per year)</title>\n <content></content>\n <figure></figure>\n </block></div>\n\n\n\n<div class=\"wp-block-column\">\n<iframe src=\"https://ourworldindata.org/grapher/share-global-excess-phosphorous?country=PRT~ESP~CHN~IND~USA~BRA~PAK\" loading=\"lazy\" style=\"width: 100%; height: 600px; border: 0px none;\"></iframe>\n</div>\n</div>\n\n\n\n<h3>Some countries could use more fertilizer; some could use less</h3>\n\n\n\n<div class=\"wp-block-columns\">\n<div class=\"wp-block-column\">\n<p>Many countries \u2013 particularly poorer countries across Sub-Saharan Africa \u2013 do not use enough fertilizer. Their crop yields suffer as a result. This is bad for farmers; food security; and the environment because it means they need to use more land for agriculture. As I covered in my <a href=\"https://ourworldindata.org/yields-habitat-loss\"><strong>recent article</strong></a>, Sub-Saharan Africa is projected to be the hotspot of habitat loss in the coming decades as a result of expanding croplands. Thousands of mammals, birds and amphibian species are at risk. The good news is that if we can improve crop yields, we can prevent almost all of this. Fertilizers will play an important role in achieving this.</p>\n\n\n\n<p>At the other end of the spectrum, some countries use too much. They could use much less \u2013 and produce much less pollution \u2013 without it affecting crop yields. Getting this balance right would bring a range of socioeconomic and environmental benefits. In a <strong><a href=\"https://ourworldindata.org/reducing-fertilizer-use\">related article</a></strong> we look at this trade-off in more detail, and explore the possible solutions for reducing nutrient pollution.</p>\n</div>\n\n\n\n<div class=\"wp-block-column\"></div>\n</div>\n" } }, "extensions": { "debug": [ { "type": "DEBUG_LOGS_INACTIVE", "message": "GraphQL Debug logging is not active. To see debug logs, GRAPHQL_DEBUG must be enabled." } ] } } |