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12028 | What the history of London’s air pollution can tell us about the future of today’s growing megacities | london-air-pollution | post | publish | <!-- wp:html --> <div class="blog-info">Our World in Data presents the data and research to make progress against the world’s largest problems. <p> </p> <p>This post draws on data and research discussed in our entry on <strong><a href="https://ourworldindata.org/air-pollution/">Air Pollution</a></strong>.</p> </div> <!-- /wp:html --> <!-- wp:paragraph --> <p>Cities in most high-income countries have relatively <a href="https://ourworldindata.org/air-pollution/#exposure-to-particulate-matter">low levels of local air pollution</a>. This, however, hasn't always been the case.</p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p>National air pollution trends often follow the <a href="https://ourworldindata.org/air-pollution/#dirty-then-clean-the-environmental-kuznets-curve-in-air-pollution">environmental kuznets curve</a> (EKC). The EKC provides a hypothesis of the link between environmental degradation and economic development: in this case, air pollution initially worsens with the onset of industrial growth, but then peaks at a certain stage of economic development and from then on pollution levels begin to decline with increased development. Many high income nations are now at the late stage of this curve, with comparably low pollution levels. Meanwhile, developing nations span various stages of the growth-to-peak phase. I have <a href="https://ourworldindata.org/air-pollution-does-it-get-worse-before-it-gets-better/">previously</a> written about this phenomenon in relation to sulphur dioxide (SO<sub>2</sub>) emissions here on Our World in Data.</p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p>If we take a historical look at pollution levels in London, for example, we see this EKC clearly. In the graph, we have plotted the average levels of suspended particulate matter (SPM) in London's air from 1700 to 2016. Suspended particulate matter (SPM) refers to fine solid or liquid particles which are suspended in Earth's atmosphere (such as soot, smoke, dust and pollen). Exposure to SPM – especially very small particles, which can more easily infiltrate the respiratory system – has been <a rel="noopener noreferrer" href="https://www.epa.gov/pm-pollution/health-and-environmental-effects-particulate-matter-pm" target="_blank">strongly linked</a> to negative cardiorespiratory health impacts, and even premature death. As we see, from 1700 on, London experienced a worsening of air pollution decade after decade. Over the course of two centuries the suspended particulate matter in London's air doubled. But at the very end of the 19th century the concentration reached a peak and then began a steep decline so that today's levels are almost 40-times lower than at that peak.</p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p>The data presented has been kindly provided by <a rel="noopener noreferrer" href="http://www.lse.ac.uk/GranthamInstitute/profile/roger-fouquet/" target="_blank">Roger Fouquet</a>, who has studied the topic of environmental quality, energy costs and economic development in great detail.{ref}Fouquet, R. (2011). Long run trends in energy-related external costs. Ecological Economics 70(12), 2380–2389. Available <a rel="noopener noreferrer" href="http://www.sciencedirect.com/science/article/pii/S0921800911002953" target="_blank">online</a>.{/ref}</p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p><iframe style="width: 100%; height: 600px; border: 0px none;" src="https://ourworldindata.org/grapher/air-pollution-london-vs-delhi" width="300" height="150"></iframe></p> <!-- /wp:paragraph --> <!-- wp:heading {"level":4} --> <h4>What explains this worsening and the subsequent improvement of London's air quality?</h4> <!-- /wp:heading --> <!-- wp:paragraph --> <p>The dominant contributor to London's historic air pollution was coal burning. Throughout the 18th and 19th centuries, the coal industry in Great Britain expanded rapidly; driven not only by economic growth, but also by an expanding labour force and improved distribution networks (such as railways and waterways).{ref}Church, R. (1986) – The History of the British Coal Industry. Vol 3. 1830–1913. Clarendon Press. Oxford.{/ref}<sup>,</sup>{ref}Flinn M.W. 1984. The History of the British Coal Industry. Vol 2. 1700-1830. Clarendon Press. Oxford{/ref} Increasing demand and falling coal prices (prices nearly halved between 1820 and 1850) led to a rapid increase in national coal consumption, rising from 20 million tonnes in 1820 to 160 million tonnes in 1900 (an eight-fold increase).{ref}Fouquet, R. (2011). Long run trends in energy-related external costs. Ecological Economics 70(12), 2380–2389. Available <a rel="noopener noreferrer" href="http://www.sciencedirect.com/science/article/pii/S0921800911002953" target="_blank">online</a>.{/ref}</p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p>The decline in air pollution can be attributed to a complex mix of factors, including <a href="https://ourworldindata.org/structural-transformation-and-deindustrialization-evidence-from-todays-rich-countries/">economic restructuring</a> away from heavy industry, switching energy sources, and increased environmental regulation.{ref}Ashworth, W. 1986. The History of the British Coal Industry. Vol 5. 1946-1982. The Nationalized Industry. Clarendon Press. Oxford.{/ref} There are thought to be three primary developments which led to this decline.{ref}Clay, K., Troesken, W., 2010. Did Frederick Brodie Discover the World's First Environmental Kuznets Curve? Coal Smoke and the Rise and Fall of the London Fog, NBER Working Papers 15669. National Bureau of Economic Research. Available <a rel="noopener noreferrer" href="http://www.nber.org/papers/w15669" target="_blank">online</a>.{/ref} Firstly, by the late 1800s, improved connectivity and commuter links allowed London's population to spread further into surrounding suburban areas, inevitably leading to an overall reduction in population density. Even if such changes did not lead to a reduction in total emissions of pollutants, the dispersal and spreading of these population centers lessened the exposure in prime pollution hotspots.</p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p>Secondly, the United Kingdom introduced its <a href="https://archive.org/details/publichealthlond00greaiala" target="_blank" rel="noopener noreferrer">Public Health Act</a> for London in 1891. Under this new regulation, businesses in London which produced excessive smoke ran the risk of financial penalties if they did not adopt cleaner and more efficient energy practices, such as switching to less polluting (but more expensive) coal sources, and ensuring fires were adequately stoked. This put increasing pressure on businesses to shift towards better and cleaner industry practice.</p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p>The third potential source of this decline was a notable shift in heating and cooking sources from coal towards gas. Uptake of gas cookers rose sharply in Great Britain during the 1800 and 1900s. The Gas Light & Coke Company—which was the leading London supplier at the time—noted that in 1892 only 2 percent of residents had a gas cooker. By 1911, this had increased to 69 percent.{ref}Goodall, F., 1999. Burning to Serve: Selling Gas in Competitive Markets. Landmark Publishing, Ashbourne.{/ref} In terms of air pollution impacts, gas is a much cleaner fuel relative to coal, meaning that such a large shift in heating and cooking sources may have contributed to the declining trend.</p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p>It's difficult to fully capture just how polluted London's air was throughout the 19th century. Throughout this period, London experienced frequent and severe fogs. Such fogs were often so dense that they halted railway journeys, interrupted general economic activities, and even contributed to London becoming a breeding ground for crime (crime rates rose sharply during these fog periods). London averaged 80 dense fog days per year, with some areas recording up to 180 in 1885.{ref}Clay, K., Troesken, W. 2010. Did Frederick Brodie Discover the World's First Environmental Kuznets Curve? Coal Smoke and the Rise and Fall of the London Fog, NBER Working Papers 15669. National Bureau of Economic Research. Available <a href="http://www.nber.org/papers/w15669" target="_blank" rel="noopener noreferrer">online</a>.{/ref}</p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p>Not only did air pollution incur a severe economic price, it also resulted in significant health costs. Air pollution deaths throughout this period rose steeply; in London, mortality from bronchitis increased from 25 deaths per 100,000 inhabitants in 1840 to 300 deaths per 100,000 in 1890. At its peak, 1-in-350 people died from bronchitis.{ref}Fouquet, R. (2011). Long run trends in energy-related external costs. Ecological Economics 70(12), 2380–2389. Available <a href="http://www.sciencedirect.com/science/article/pii/S0921800911002953" target="_blank" rel="noopener noreferrer">online</a>.{/ref}</p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p>Although London was arguably one of the worst polluted cities during this time (and often referred to as the "Big Smoke"), many other industrial cities across Great Britain (and indeed across other nations) experienced similar air pollution problems. In the photograph below, we see pollution in Widnes, an industrial town close to Liverpool, in the late 19th century.</p> <!-- /wp:paragraph --> <!-- wp:columns {"className":"is-style-sticky-right"} --> <div class="wp-block-columns is-style-sticky-right"><!-- wp:column --> <div class="wp-block-column"><!-- wp:heading {"level":6} --> <h6>Air pollution in Widnes, late 19th century{ref}Hardie, D. W. F., A History of the Chemical Industry in Widnes, Imperial Chemical Industries Limited, 1950. Available <a href="https://commons.wikimedia.org/wiki/File:Widnes_Smoke.jpg" target="_blank" rel="noopener noreferrer">online</a>.{/ref}</h6> <!-- /wp:heading --> <!-- wp:image {"align":"center","id":12032} --> <div class="wp-block-image"><figure class="aligncenter"><img src="https://ourworldindata.org/app/uploads/2017/06/1024px-Widnes_Smoke-750x424.jpg" alt="" class="wp-image-12032"/></figure></div> <!-- /wp:image --></div> <!-- /wp:column --> <!-- wp:column --> <div class="wp-block-column"></div> <!-- /wp:column --></div> <!-- /wp:columns --> <!-- wp:heading {"level":3} --> <h3>London vs. today's developing cities</h3> <!-- /wp:heading --> <!-- wp:paragraph {"align":"left"} --> <p class="has-text-align-left">From our first chart, we see that concentrations of suspended particulate matter (SPM) reached up to 623 micrograms per cubic metre. This figure will be meaningless to most without proper context. Let's therefore compare historic London concentrations to those experienced in recent years in New Delhi—one of the world's <a href="https://www.theguardian.com/cities/datablog/2017/feb/13/most-polluted-cities-world-listed-region" target="_blank" rel="noopener noreferrer">most polluted cities</a> today.</p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p>In the first chart above, we can add SPM trends for Delhi from the later 1990's to 2010 using the 'add city' button.{ref}Note that these figures are sourced from the Government of India's Economic Survey of Delhi (2012-13). From 2010 onwards, the government provides a further breakdown to its air pollution measurements based on particle size categories, and typically does not report on total SPM. As such, comparable post-2010 data is not available.{/ref}</p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p>What we see is that concentrations in Delhi range from around 450 to 500 micrograms per cubic metre. This is extremely high, but remains lower than peak concentrations in London during its rapid industrialization. It is wrong to assume that today's major developing cities—such as Delhi, Beijing, Jakarta, Karachi—are experiencing unprecedented levels of air pollution. It's likely that many of today's high-income cities have gone through similar periods of high (or higher) pollution levels. Perhaps what differentiates today's transitioning cities is the population sizes which inhabit them; exposure to such pollution undoubtedly leads to <a href="https://ourworldindata.org/air-pollution-post">high mortality figures in absolute terms</a>.{ref}The absolute number of people dying prematurely from air pollution impacts has been increasing; this is despite an overall decline in the death rate (measured as deaths per 100,000 individuals) across the majority of countries in recent decades. The reason absolute numbers of deaths are increasing despite falling death rates can be attributed to population and demographic factors: population growth (and the additional impact of an aging population) has been outpacing the rate of reduction in death rates. Overall, this leads to an increase in deaths in absolute terms.{/ref}</p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p>If we see air pollution as a by-product of <a href="https://ourworldindata.org/economic-growth">economic and industrial development</a>, an appropriate comparison would be based on levels of prosperity, rather than versus time. In the chart below we have plotted the same trends in SPM (on the y-axis) for London and Delhi, but now map these levels relative to gross domestic product (GDP) per capita (on the x-axis). These GDP per capita figures are adjusted for inflation and <a href="https://ourworldindata.org/what-are-ppps">expressed in international dollars</a> to reflect differences in living costs.</p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p>Interestingly, if we observe the evolution of these trends with time, we see that at a given level of GDP per capita, Delhi's air pollution levels have, and continue to, follow a similar pathway to that of London in the 19th century.</p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p>But the often-forgotten history of air pollution in today's rich countries offers an important lesson about what is possible for world regions with lower levels of prosperity today. After air pollution worsens at the initial stages of development it declines at later stages and can reach historically low levels.</p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p>The key for Delhi and other transitioning cities will therefore be to continue shifting rightwards (increasing GDP per capita), but to try to peak below London's 19th century pathway. If they can achieve this, then they will have succeeded in developing in a cleaner way than today's high income cities.</p> <!-- /wp:paragraph --> <!-- wp:paragraph --> <p><iframe style="width: 100%; height: 600px; border: 0px none;" src="https://ourworldindata.org/grapher/air-pollution-vs-gdp-per-capita?time=1700..2015" width="300" height="150"></iframe></p> <!-- /wp:paragraph --> | { "id": "wp-12028", "slug": "london-air-pollution", "content": { "toc": [], "body": [ { "type": "text", "value": [ { "text": "Our World in Data presents the data and research to make progress against the world\u2019s largest problems.\n", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "This post draws on data and research discussed in our entry on ", "spanType": "span-simple-text" }, { "children": [ { "url": "https://ourworldindata.org/air-pollution/", "children": [ { "text": "Air Pollution", "spanType": "span-simple-text" } ], "spanType": "span-link" } ], "spanType": "span-bold" }, { "text": ".", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "Cities in most high-income countries have relatively ", "spanType": "span-simple-text" }, { "url": "https://ourworldindata.org/air-pollution/#exposure-to-particulate-matter", "children": [ { "text": "low levels of local air pollution", "spanType": "span-simple-text" } ], "spanType": "span-link" }, { "text": ". This, however, hasn't always been the case.", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "National air pollution trends often\u00a0follow the ", "spanType": "span-simple-text" }, { "url": "https://ourworldindata.org/air-pollution/#dirty-then-clean-the-environmental-kuznets-curve-in-air-pollution", "children": [ { "text": "environmental kuznets curve", "spanType": "span-simple-text" } ], "spanType": "span-link" }, { "text": " (EKC). The EKC provides a hypothesis of the link between environmental degradation and economic development: in this case, air pollution\u00a0initially worsens with the onset of industrial growth, but then peaks at a certain stage of economic development and from then on pollution levels begin to decline\u00a0with increased development. Many high income nations are now at the late stage of this curve, with comparably low pollution levels. Meanwhile, developing nations span various stages of the growth-to-peak phase. I have ", "spanType": "span-simple-text" }, { "url": "https://ourworldindata.org/air-pollution-does-it-get-worse-before-it-gets-better/", "children": [ { "text": "previously", "spanType": "span-simple-text" } ], "spanType": "span-link" }, { "text": " written about this phenomenon in relation to sulphur dioxide (SO", "spanType": "span-simple-text" }, { "children": [ { "text": "2", "spanType": "span-simple-text" } ], "spanType": "span-subscript" }, { "text": ") emissions here on Our World in Data.", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "If we take a historical\u00a0look at pollution levels in London, for example, we see this EKC clearly. In the graph, we have plotted the average\u00a0levels of suspended particulate matter (SPM) in London's air from 1700 to 2016. Suspended particulate matter (SPM) refers to fine solid or liquid particles which are suspended in Earth's atmosphere (such as soot, smoke, dust and pollen). Exposure to SPM \u2013 especially very small particles, which can more easily infiltrate the respiratory system \u2013 has been ", "spanType": "span-simple-text" }, { "url": "https://www.epa.gov/pm-pollution/health-and-environmental-effects-particulate-matter-pm", "children": [ { "text": "strongly linked", "spanType": "span-simple-text" } ], "spanType": "span-link" }, { "text": " to negative cardiorespiratory health impacts, and even premature death. As we see, from\u00a01700 on, London experienced a worsening of air pollution decade after decade. Over the course of two centuries the suspended particulate matter in London's air doubled. 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Available ", "spanType": "span-simple-text" }, { "url": "http://www.sciencedirect.com/science/article/pii/S0921800911002953", "children": [ { "text": "online", "spanType": "span-simple-text" } ], "spanType": "span-link" }, { "text": ".{/ref}", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "text": [ { "text": "What explains this worsening and the subsequent improvement of London's air quality?", "spanType": "span-simple-text" } ], "type": "heading", "level": 3, "parseErrors": [] }, { "type": "text", "value": [ { "text": "The dominant contributor to London's historic air pollution was coal burning. Throughout the 18th and 19th centuries, the coal industry in Great Britain expanded rapidly; driven not only by economic growth, but also by an expanding labour force and improved distribution networks (such as railways and waterways).{ref}Church, R. (1986) \u2013 The History of the British Coal Industry. Vol 3. 1830\u20131913. Clarendon Press. Oxford.{/ref}", "spanType": "span-simple-text" }, { "children": [ { "text": ",", "spanType": "span-simple-text" } ], "spanType": "span-superscript" }, { "text": "{ref}Flinn M.W. 1984. The History of the British Coal Industry. Vol 2. 1700-1830. Clarendon Press. Oxford{/ref} Increasing demand and falling coal prices (prices nearly halved between 1820 and 1850) led to a rapid increase in national coal consumption, rising from 20 million tonnes in 1820 to 160 million tonnes in 1900 (an eight-fold increase).{ref}Fouquet, R. (2011). Long run trends in energy-related external costs. Ecological Economics 70(12), 2380\u20132389. Available ", "spanType": "span-simple-text" }, { "url": "http://www.sciencedirect.com/science/article/pii/S0921800911002953", "children": [ { "text": "online", "spanType": "span-simple-text" } ], "spanType": "span-link" }, { "text": ".{/ref}", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "The decline in air pollution can be attributed to a complex mix\u00a0of factors, including ", "spanType": "span-simple-text" }, { "url": "https://ourworldindata.org/structural-transformation-and-deindustrialization-evidence-from-todays-rich-countries/", "children": [ { "text": "economic restructuring", "spanType": "span-simple-text" } ], "spanType": "span-link" }, { "text": " away from heavy industry, switching energy sources, and increased environmental regulation.{ref}Ashworth, W. 1986. The History of the British Coal Industry. Vol 5. 1946-1982. The Nationalized Industry. Clarendon Press. Oxford.{/ref} There are thought to be three primary developments which led to this decline.{ref}Clay, K., Troesken, W., 2010. Did Frederick Brodie Discover the World's First Environmental Kuznets Curve? Coal Smoke and the Rise and Fall of the London Fog, NBER Working Papers 15669. National Bureau of Economic Research. Available ", "spanType": "span-simple-text" }, { "url": "http://www.nber.org/papers/w15669", "children": [ { "text": "online", "spanType": "span-simple-text" } ], "spanType": "span-link" }, { "text": ".{/ref} Firstly, by the late 1800s, improved connectivity and commuter links allowed London's population to spread further into surrounding suburban areas, inevitably leading to an overall reduction in population density. Even if such changes did not lead to a reduction in total emissions of pollutants, the dispersal and spreading of these population centers lessened the exposure in prime pollution hotspots.", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "Secondly, the United Kingdom introduced its ", "spanType": "span-simple-text" }, { "url": "https://archive.org/details/publichealthlond00greaiala", "children": [ { "text": "Public Health Act", "spanType": "span-simple-text" } ], "spanType": "span-link" }, { "text": " for London in 1891. Under this new regulation, businesses in London which produced excessive smoke ran the risk of financial penalties if they did not adopt cleaner and more efficient energy practices, such as switching to less polluting (but more expensive) coal sources, and ensuring fires were adequately stoked. This put increasing pressure on businesses to shift towards better and cleaner industry practice.", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "The third potential source of this decline was a notable shift in heating and cooking sources from coal towards gas. Uptake of gas cookers rose sharply in Great Britain during the 1800 and 1900s. The Gas Light & Coke Company\u2014which was the leading London supplier at the time\u2014noted that in 1892 only 2 percent of residents had a gas cooker. By 1911, this had increased to 69 percent.{ref}Goodall, F., 1999. Burning to Serve: Selling Gas in Competitive Markets. Landmark Publishing, Ashbourne.{/ref} In terms of air pollution impacts, gas is a much cleaner fuel relative to coal, meaning that such a large shift in heating and cooking sources may have contributed to the declining trend.", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "It's difficult to fully capture just how polluted London's air was throughout the 19th century. Throughout this period, London experienced frequent and severe fogs. Such fogs were often so dense that they halted railway journeys, interrupted general economic activities, and even contributed to London becoming a breeding ground for crime (crime rates rose sharply during these fog periods). London averaged 80 dense fog days per year, with some areas recording up to 180 in 1885.{ref}Clay, K., Troesken, W. 2010. Did Frederick Brodie Discover the World's First Environmental Kuznets Curve? Coal Smoke and the Rise and Fall of the London Fog, NBER Working Papers 15669. National Bureau of Economic Research. Available ", "spanType": "span-simple-text" }, { "url": "http://www.nber.org/papers/w15669", "children": [ { "text": "online", "spanType": "span-simple-text" } ], "spanType": "span-link" }, { "text": ".{/ref}", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "Not only did air pollution\u00a0incur a severe economic price, it also resulted in significant health costs. Air pollution deaths throughout this period rose steeply; in London, mortality from bronchitis increased from 25 deaths per 100,000 inhabitants in 1840 to 300 deaths per 100,000 in 1890. At its peak, 1-in-350 people died from bronchitis.{ref}Fouquet, R. (2011). Long run trends in energy-related external costs. Ecological Economics 70(12), 2380\u20132389. Available ", "spanType": "span-simple-text" }, { "url": "http://www.sciencedirect.com/science/article/pii/S0921800911002953", "children": [ { "text": "online", "spanType": "span-simple-text" } ], "spanType": "span-link" }, { "text": ".{/ref}", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "Although London was arguably one of the worst polluted cities during this time (and often referred to as the \"Big Smoke\"), many other industrial cities across Great Britain (and indeed across other nations) experienced similar air pollution problems. In the photograph\u00a0below, we see pollution in Widnes, an industrial town close to Liverpool, in the late 19th century.", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "text": [ { "text": "Air pollution in Widnes, late 19th century{ref}Hardie, D. W. F., A History of the Chemical Industry in Widnes, Imperial Chemical Industries Limited, 1950. Available ", "spanType": "span-simple-text" }, { "url": "https://commons.wikimedia.org/wiki/File:Widnes_Smoke.jpg", "children": [ { "text": "online", "spanType": "span-simple-text" } ], "spanType": "span-link" }, { "text": ".{/ref}", "spanType": "span-simple-text" } ], "type": "heading", "level": 5, "parseErrors": [] }, { "alt": "", "size": "wide", "type": "image", "filename": "1024px-Widnes_Smoke.jpg", "parseErrors": [] }, { "text": [ { "text": "London vs. today's developing cities", "spanType": "span-simple-text" } ], "type": "heading", "level": 2, "parseErrors": [] }, { "type": "text", "value": [ { "text": "From our first chart, we see that concentrations of\u00a0suspended particulate matter (SPM) reached up to 623 micrograms per cubic metre. This figure will be meaningless to most without proper context. Let's therefore compare historic London concentrations to those experienced in recent years in New Delhi\u2014one of the world's ", "spanType": "span-simple-text" }, { "url": "https://www.theguardian.com/cities/datablog/2017/feb/13/most-polluted-cities-world-listed-region", "children": [ { "text": "most polluted cities", "spanType": "span-simple-text" } ], "spanType": "span-link" }, { "text": " today.", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "In the first chart above, we can add SPM trends for Delhi from the later 1990's to 2010 using the 'add city' button.{ref}Note that these figures are sourced from the Government of India's Economic Survey of Delhi (2012-13). From 2010 onwards, the government provides a further breakdown to its air pollution measurements based on particle size categories, and typically does not report on total SPM. As such, comparable post-2010 data is not available.{/ref}", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "What we see is that concentrations in Delhi range from around 450 to 500 micrograms per cubic metre.\u00a0This is extremely high, but remains lower than peak concentrations in London during its rapid industrialization. It is wrong to assume that today's major developing cities\u2014such as Delhi, Beijing, Jakarta, Karachi\u2014are experiencing unprecedented levels of air pollution. It's likely that many of today's high-income cities have gone through similar periods of high (or higher) pollution levels. Perhaps what differentiates today's transitioning cities is the population sizes which inhabit them; exposure to such pollution undoubtedly leads to ", "spanType": "span-simple-text" }, { "url": "https://ourworldindata.org/air-pollution-post", "children": [ { "text": "high mortality figures in absolute terms", "spanType": "span-simple-text" } ], "spanType": "span-link" }, { "text": ".{ref}The absolute number of people dying prematurely from air pollution impacts has been increasing; this is despite an overall decline in the death rate (measured as deaths per 100,000 individuals) across the majority of countries in recent decades. The reason absolute numbers of deaths are increasing despite falling death rates can be attributed to population and demographic factors: population growth (and the additional impact of an aging population) has been outpacing the rate of reduction in death rates. Overall, this leads to an increase in deaths in absolute terms.{/ref}", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "If we see air pollution as a by-product of ", "spanType": "span-simple-text" }, { "url": "https://ourworldindata.org/economic-growth", "children": [ { "text": "economic and industrial development", "spanType": "span-simple-text" } ], "spanType": "span-link" }, { "text": ", an appropriate comparison would be based on levels of prosperity, rather than versus time. In the chart below we have plotted the same trends in SPM (on the y-axis) for London and Delhi, but now map these levels relative to gross domestic product (GDP) per capita (on the x-axis). These GDP per capita figures are adjusted for inflation and ", "spanType": "span-simple-text" }, { "url": "https://ourworldindata.org/what-are-ppps", "children": [ { "text": "expressed in international dollars", "spanType": "span-simple-text" } ], "spanType": "span-link" }, { "text": " to reflect differences in living costs.", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "Interestingly, if we observe the evolution of these trends with time, we see that at a given level of GDP per capita, Delhi's air pollution levels have, and continue to, follow a similar pathway to that of London in the 19th century.", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "But the often-forgotten history of air pollution in today's rich countries offers an important lesson about what is possible for world regions with lower levels of prosperity today. After air pollution worsens at the initial stages of development it declines at later stages and can reach historically low levels.", "spanType": "span-simple-text" } ], "parseErrors": [] }, { "type": "text", "value": [ { "text": "The key for Delhi and other transitioning cities will therefore be to continue shifting rightwards (increasing GDP per capita), but to try to peak below London's 19th century pathway. If they can achieve this, then they will have succeeded in developing in a cleaner way than today's high income cities.", "spanType": "span-simple-text" } ], "parseErrors": [] } ], "type": "article", "title": "What the history of London\u2019s air pollution can tell us about the future of today\u2019s growing megacities", "authors": [ "Hannah Ritchie" ], "dateline": "June 20, 2017", "sidebar-toc": false, "featured-image": "air-pollution-london-vs-delhi.png" }, "createdAt": "2017-06-11T16:58:09.000Z", "published": false, "updatedAt": "2023-10-11T09:49:59.000Z", "revisionId": null, "publishedAt": "2017-06-20T08:51:42.000Z", "relatedCharts": [], "publicationContext": "listed" } |
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2017-06-20 08:51:42 | 2024-02-16 14:22:46 | 1VdG5DIp_2iiIYIGHolHayup6v1p9miRcG4J4M3gJmp0 | [ "Hannah Ritchie" ] |
2017-06-11 16:58:09 | 2023-10-11 09:49:59 | https://ourworldindata.org/wp-content/uploads/2017/06/air-pollution-london-vs-delhi.png | {} |
Our World in Data presents the data and research to make progress against the world’s largest problems. This post draws on data and research discussed in our entry on **[Air Pollution](https://ourworldindata.org/air-pollution/)**. Cities in most high-income countries have relatively [low levels of local air pollution](https://ourworldindata.org/air-pollution/#exposure-to-particulate-matter). This, however, hasn't always been the case. National air pollution trends often follow the [environmental kuznets curve](https://ourworldindata.org/air-pollution/#dirty-then-clean-the-environmental-kuznets-curve-in-air-pollution) (EKC). The EKC provides a hypothesis of the link between environmental degradation and economic development: in this case, air pollution initially worsens with the onset of industrial growth, but then peaks at a certain stage of economic development and from then on pollution levels begin to decline with increased development. Many high income nations are now at the late stage of this curve, with comparably low pollution levels. Meanwhile, developing nations span various stages of the growth-to-peak phase. I have [previously](https://ourworldindata.org/air-pollution-does-it-get-worse-before-it-gets-better/) written about this phenomenon in relation to sulphur dioxide (SO2) emissions here on Our World in Data. If we take a historical look at pollution levels in London, for example, we see this EKC clearly. In the graph, we have plotted the average levels of suspended particulate matter (SPM) in London's air from 1700 to 2016. Suspended particulate matter (SPM) refers to fine solid or liquid particles which are suspended in Earth's atmosphere (such as soot, smoke, dust and pollen). Exposure to SPM – especially very small particles, which can more easily infiltrate the respiratory system – has been [strongly linked](https://www.epa.gov/pm-pollution/health-and-environmental-effects-particulate-matter-pm) to negative cardiorespiratory health impacts, and even premature death. As we see, from 1700 on, London experienced a worsening of air pollution decade after decade. Over the course of two centuries the suspended particulate matter in London's air doubled. But at the very end of the 19th century the concentration reached a peak and then began a steep decline so that today's levels are almost 40-times lower than at that peak. The data presented has been kindly provided by [Roger Fouquet](http://www.lse.ac.uk/GranthamInstitute/profile/roger-fouquet/), who has studied the topic of environmental quality, energy costs and economic development in great detail.{ref}Fouquet, R. (2011). Long run trends in energy-related external costs. Ecological Economics 70(12), 2380–2389. Available [online](http://www.sciencedirect.com/science/article/pii/S0921800911002953).{/ref} ### What explains this worsening and the subsequent improvement of London's air quality? The dominant contributor to London's historic air pollution was coal burning. Throughout the 18th and 19th centuries, the coal industry in Great Britain expanded rapidly; driven not only by economic growth, but also by an expanding labour force and improved distribution networks (such as railways and waterways).{ref}Church, R. (1986) – The History of the British Coal Industry. Vol 3. 1830–1913. Clarendon Press. Oxford.{/ref},{ref}Flinn M.W. 1984. The History of the British Coal Industry. Vol 2. 1700-1830. Clarendon Press. Oxford{/ref} Increasing demand and falling coal prices (prices nearly halved between 1820 and 1850) led to a rapid increase in national coal consumption, rising from 20 million tonnes in 1820 to 160 million tonnes in 1900 (an eight-fold increase).{ref}Fouquet, R. (2011). Long run trends in energy-related external costs. Ecological Economics 70(12), 2380–2389. Available [online](http://www.sciencedirect.com/science/article/pii/S0921800911002953).{/ref} The decline in air pollution can be attributed to a complex mix of factors, including [economic restructuring](https://ourworldindata.org/structural-transformation-and-deindustrialization-evidence-from-todays-rich-countries/) away from heavy industry, switching energy sources, and increased environmental regulation.{ref}Ashworth, W. 1986. The History of the British Coal Industry. Vol 5. 1946-1982. The Nationalized Industry. Clarendon Press. Oxford.{/ref} There are thought to be three primary developments which led to this decline.{ref}Clay, K., Troesken, W., 2010. Did Frederick Brodie Discover the World's First Environmental Kuznets Curve? Coal Smoke and the Rise and Fall of the London Fog, NBER Working Papers 15669. National Bureau of Economic Research. Available [online](http://www.nber.org/papers/w15669).{/ref} Firstly, by the late 1800s, improved connectivity and commuter links allowed London's population to spread further into surrounding suburban areas, inevitably leading to an overall reduction in population density. Even if such changes did not lead to a reduction in total emissions of pollutants, the dispersal and spreading of these population centers lessened the exposure in prime pollution hotspots. Secondly, the United Kingdom introduced its [Public Health Act](https://archive.org/details/publichealthlond00greaiala) for London in 1891. Under this new regulation, businesses in London which produced excessive smoke ran the risk of financial penalties if they did not adopt cleaner and more efficient energy practices, such as switching to less polluting (but more expensive) coal sources, and ensuring fires were adequately stoked. This put increasing pressure on businesses to shift towards better and cleaner industry practice. The third potential source of this decline was a notable shift in heating and cooking sources from coal towards gas. Uptake of gas cookers rose sharply in Great Britain during the 1800 and 1900s. The Gas Light & Coke Company—which was the leading London supplier at the time—noted that in 1892 only 2 percent of residents had a gas cooker. By 1911, this had increased to 69 percent.{ref}Goodall, F., 1999. Burning to Serve: Selling Gas in Competitive Markets. Landmark Publishing, Ashbourne.{/ref} In terms of air pollution impacts, gas is a much cleaner fuel relative to coal, meaning that such a large shift in heating and cooking sources may have contributed to the declining trend. It's difficult to fully capture just how polluted London's air was throughout the 19th century. Throughout this period, London experienced frequent and severe fogs. Such fogs were often so dense that they halted railway journeys, interrupted general economic activities, and even contributed to London becoming a breeding ground for crime (crime rates rose sharply during these fog periods). London averaged 80 dense fog days per year, with some areas recording up to 180 in 1885.{ref}Clay, K., Troesken, W. 2010. Did Frederick Brodie Discover the World's First Environmental Kuznets Curve? Coal Smoke and the Rise and Fall of the London Fog, NBER Working Papers 15669. National Bureau of Economic Research. Available [online](http://www.nber.org/papers/w15669).{/ref} Not only did air pollution incur a severe economic price, it also resulted in significant health costs. Air pollution deaths throughout this period rose steeply; in London, mortality from bronchitis increased from 25 deaths per 100,000 inhabitants in 1840 to 300 deaths per 100,000 in 1890. At its peak, 1-in-350 people died from bronchitis.{ref}Fouquet, R. (2011). Long run trends in energy-related external costs. Ecological Economics 70(12), 2380–2389. Available [online](http://www.sciencedirect.com/science/article/pii/S0921800911002953).{/ref} Although London was arguably one of the worst polluted cities during this time (and often referred to as the "Big Smoke"), many other industrial cities across Great Britain (and indeed across other nations) experienced similar air pollution problems. In the photograph below, we see pollution in Widnes, an industrial town close to Liverpool, in the late 19th century. ##### Air pollution in Widnes, late 19th century{ref}Hardie, D. W. F., A History of the Chemical Industry in Widnes, Imperial Chemical Industries Limited, 1950. Available [online](https://commons.wikimedia.org/wiki/File:Widnes_Smoke.jpg).{/ref} <Image filename="1024px-Widnes_Smoke.jpg" alt=""/> ## London vs. today's developing cities From our first chart, we see that concentrations of suspended particulate matter (SPM) reached up to 623 micrograms per cubic metre. This figure will be meaningless to most without proper context. Let's therefore compare historic London concentrations to those experienced in recent years in New Delhi—one of the world's [most polluted cities](https://www.theguardian.com/cities/datablog/2017/feb/13/most-polluted-cities-world-listed-region) today. In the first chart above, we can add SPM trends for Delhi from the later 1990's to 2010 using the 'add city' button.{ref}Note that these figures are sourced from the Government of India's Economic Survey of Delhi (2012-13). From 2010 onwards, the government provides a further breakdown to its air pollution measurements based on particle size categories, and typically does not report on total SPM. As such, comparable post-2010 data is not available.{/ref} What we see is that concentrations in Delhi range from around 450 to 500 micrograms per cubic metre. This is extremely high, but remains lower than peak concentrations in London during its rapid industrialization. It is wrong to assume that today's major developing cities—such as Delhi, Beijing, Jakarta, Karachi—are experiencing unprecedented levels of air pollution. It's likely that many of today's high-income cities have gone through similar periods of high (or higher) pollution levels. Perhaps what differentiates today's transitioning cities is the population sizes which inhabit them; exposure to such pollution undoubtedly leads to [high mortality figures in absolute terms](https://ourworldindata.org/air-pollution-post).{ref}The absolute number of people dying prematurely from air pollution impacts has been increasing; this is despite an overall decline in the death rate (measured as deaths per 100,000 individuals) across the majority of countries in recent decades. The reason absolute numbers of deaths are increasing despite falling death rates can be attributed to population and demographic factors: population growth (and the additional impact of an aging population) has been outpacing the rate of reduction in death rates. Overall, this leads to an increase in deaths in absolute terms.{/ref} If we see air pollution as a by-product of [economic and industrial development](https://ourworldindata.org/economic-growth), an appropriate comparison would be based on levels of prosperity, rather than versus time. In the chart below we have plotted the same trends in SPM (on the y-axis) for London and Delhi, but now map these levels relative to gross domestic product (GDP) per capita (on the x-axis). These GDP per capita figures are adjusted for inflation and [expressed in international dollars](https://ourworldindata.org/what-are-ppps) to reflect differences in living costs. Interestingly, if we observe the evolution of these trends with time, we see that at a given level of GDP per capita, Delhi's air pollution levels have, and continue to, follow a similar pathway to that of London in the 19th century. But the often-forgotten history of air pollution in today's rich countries offers an important lesson about what is possible for world regions with lower levels of prosperity today. After air pollution worsens at the initial stages of development it declines at later stages and can reach historically low levels. The key for Delhi and other transitioning cities will therefore be to continue shifting rightwards (increasing GDP per capita), but to try to peak below London's 19th century pathway. If they can achieve this, then they will have succeeded in developing in a cleaner way than today's high income cities. | { "id": 12028, "date": "2017-06-20T09:51:42", "guid": { "rendered": "https://ourworldindata.org/?p=12028" }, "link": "https://owid.cloud/london-air-pollution", "meta": { "owid_publication_context_meta_field": { "latest": true, "homepage": true, "immediate_newsletter": true } }, "slug": "london-air-pollution", "tags": [ 153 ], "type": "post", "title": { "rendered": "What the history of London\u2019s air pollution can tell us about the future of today\u2019s growing megacities" }, "_links": { "self": [ { "href": "https://owid.cloud/wp-json/wp/v2/posts/12028" } ], "about": [ { "href": "https://owid.cloud/wp-json/wp/v2/types/post" } ], "author": [ { "href": "https://owid.cloud/wp-json/wp/v2/users/17", "embeddable": true } ], "curies": [ { "href": "https://api.w.org/{rel}", "name": "wp", "templated": true } ], "replies": [ { "href": "https://owid.cloud/wp-json/wp/v2/comments?post=12028", "embeddable": true } ], "wp:term": [ { "href": "https://owid.cloud/wp-json/wp/v2/categories?post=12028", "taxonomy": "category", "embeddable": true }, { "href": "https://owid.cloud/wp-json/wp/v2/tags?post=12028", "taxonomy": "post_tag", "embeddable": true } ], "collection": [ { "href": "https://owid.cloud/wp-json/wp/v2/posts" } ], "wp:attachment": [ { "href": "https://owid.cloud/wp-json/wp/v2/media?parent=12028" } ], "version-history": [ { "href": "https://owid.cloud/wp-json/wp/v2/posts/12028/revisions", "count": 18 } ], "wp:featuredmedia": [ { "href": "https://owid.cloud/wp-json/wp/v2/media/12036", "embeddable": true } ], "predecessor-version": [ { "id": 58645, "href": "https://owid.cloud/wp-json/wp/v2/posts/12028/revisions/58645" } ] }, "author": 17, "format": "standard", "status": "publish", "sticky": false, "content": { "rendered": "\n<div class=\"blog-info\">Our World in Data presents the data and research to make progress against the world\u2019s largest problems.\n<p> </p>\n<p>This post draws on data and research discussed in our entry on <strong><a href=\"https://ourworldindata.org/air-pollution/\">Air Pollution</a></strong>.</p>\n</div>\n\n\n\n<p>Cities in most high-income countries have relatively <a href=\"https://ourworldindata.org/air-pollution/#exposure-to-particulate-matter\">low levels of local air pollution</a>. This, however, hasn’t always been the case.</p>\n\n\n\n<p>National air pollution trends often follow the <a href=\"https://ourworldindata.org/air-pollution/#dirty-then-clean-the-environmental-kuznets-curve-in-air-pollution\">environmental kuznets curve</a> (EKC). The EKC provides a hypothesis of the link between environmental degradation and economic development: in this case, air pollution initially worsens with the onset of industrial growth, but then peaks at a certain stage of economic development and from then on pollution levels begin to decline with increased development. Many high income nations are now at the late stage of this curve, with comparably low pollution levels. Meanwhile, developing nations span various stages of the growth-to-peak phase. I have <a href=\"https://ourworldindata.org/air-pollution-does-it-get-worse-before-it-gets-better/\">previously</a> written about this phenomenon in relation to sulphur dioxide (SO<sub>2</sub>) emissions here on Our World in Data.</p>\n\n\n\n<p>If we take a historical look at pollution levels in London, for example, we see this EKC clearly. In the graph, we have plotted the average levels of suspended particulate matter (SPM) in London’s air from 1700 to 2016. Suspended particulate matter (SPM) refers to fine solid or liquid particles which are suspended in Earth’s atmosphere (such as soot, smoke, dust and pollen). Exposure to SPM \u2013 especially very small particles, which can more easily infiltrate the respiratory system \u2013 has been <a rel=\"noopener noreferrer\" href=\"https://www.epa.gov/pm-pollution/health-and-environmental-effects-particulate-matter-pm\" target=\"_blank\">strongly linked</a> to negative cardiorespiratory health impacts, and even premature death. As we see, from 1700 on, London experienced a worsening of air pollution decade after decade. Over the course of two centuries the suspended particulate matter in London’s air doubled. But at the very end of the 19th century the concentration reached a peak and then began a steep decline so that today’s levels are almost 40-times lower than at that peak.</p>\n\n\n\n<p>The data presented has been kindly provided by <a rel=\"noopener noreferrer\" href=\"http://www.lse.ac.uk/GranthamInstitute/profile/roger-fouquet/\" target=\"_blank\">Roger Fouquet</a>, who has studied the topic of environmental quality, energy costs and economic development in great detail.{ref}Fouquet, R. (2011). Long run trends in energy-related external costs. Ecological Economics 70(12), 2380\u20132389. Available <a rel=\"noopener noreferrer\" href=\"http://www.sciencedirect.com/science/article/pii/S0921800911002953\" target=\"_blank\">online</a>.{/ref}</p>\n\n\n\n<p><iframe loading=\"lazy\" style=\"width: 100%; height: 600px; border: 0px none;\" src=\"https://ourworldindata.org/grapher/air-pollution-london-vs-delhi\" width=\"300\" height=\"150\"></iframe></p>\n\n\n\n<h4>What explains this worsening and the subsequent improvement of London’s air quality?</h4>\n\n\n\n<p>The dominant contributor to London’s historic air pollution was coal burning. Throughout the 18th and 19th centuries, the coal industry in Great Britain expanded rapidly; driven not only by economic growth, but also by an expanding labour force and improved distribution networks (such as railways and waterways).{ref}Church, R. (1986) \u2013 The History of the British Coal Industry. Vol 3. 1830\u20131913. Clarendon Press. Oxford.{/ref}<sup>,</sup>{ref}Flinn M.W. 1984. The History of the British Coal Industry. Vol 2. 1700-1830. Clarendon Press. Oxford{/ref} Increasing demand and falling coal prices (prices nearly halved between 1820 and 1850) led to a rapid increase in national coal consumption, rising from 20 million tonnes in 1820 to 160 million tonnes in 1900 (an eight-fold increase).{ref}Fouquet, R. (2011). Long run trends in energy-related external costs. Ecological Economics 70(12), 2380\u20132389. Available <a rel=\"noopener noreferrer\" href=\"http://www.sciencedirect.com/science/article/pii/S0921800911002953\" target=\"_blank\">online</a>.{/ref}</p>\n\n\n\n<p>The decline in air pollution can be attributed to a complex mix of factors, including <a href=\"https://ourworldindata.org/structural-transformation-and-deindustrialization-evidence-from-todays-rich-countries/\">economic restructuring</a> away from heavy industry, switching energy sources, and increased environmental regulation.{ref}Ashworth, W. 1986. The History of the British Coal Industry. Vol 5. 1946-1982. The Nationalized Industry. Clarendon Press. Oxford.{/ref} There are thought to be three primary developments which led to this decline.{ref}Clay, K., Troesken, W., 2010. Did Frederick Brodie Discover the World’s First Environmental Kuznets Curve? Coal Smoke and the Rise and Fall of the London Fog, NBER Working Papers 15669. National Bureau of Economic Research. Available <a rel=\"noopener noreferrer\" href=\"http://www.nber.org/papers/w15669\" target=\"_blank\">online</a>.{/ref} Firstly, by the late 1800s, improved connectivity and commuter links allowed London’s population to spread further into surrounding suburban areas, inevitably leading to an overall reduction in population density. Even if such changes did not lead to a reduction in total emissions of pollutants, the dispersal and spreading of these population centers lessened the exposure in prime pollution hotspots.</p>\n\n\n\n<p>Secondly, the United Kingdom introduced its <a href=\"https://archive.org/details/publichealthlond00greaiala\" target=\"_blank\" rel=\"noopener noreferrer\">Public Health Act</a> for London in 1891. Under this new regulation, businesses in London which produced excessive smoke ran the risk of financial penalties if they did not adopt cleaner and more efficient energy practices, such as switching to less polluting (but more expensive) coal sources, and ensuring fires were adequately stoked. This put increasing pressure on businesses to shift towards better and cleaner industry practice.</p>\n\n\n\n<p>The third potential source of this decline was a notable shift in heating and cooking sources from coal towards gas. Uptake of gas cookers rose sharply in Great Britain during the 1800 and 1900s. The Gas Light & Coke Company\u2014which was the leading London supplier at the time\u2014noted that in 1892 only 2 percent of residents had a gas cooker. By 1911, this had increased to 69 percent.{ref}Goodall, F., 1999. Burning to Serve: Selling Gas in Competitive Markets. Landmark Publishing, Ashbourne.{/ref} In terms of air pollution impacts, gas is a much cleaner fuel relative to coal, meaning that such a large shift in heating and cooking sources may have contributed to the declining trend.</p>\n\n\n\n<p>It’s difficult to fully capture just how polluted London’s air was throughout the 19th century. Throughout this period, London experienced frequent and severe fogs. Such fogs were often so dense that they halted railway journeys, interrupted general economic activities, and even contributed to London becoming a breeding ground for crime (crime rates rose sharply during these fog periods). London averaged 80 dense fog days per year, with some areas recording up to 180 in 1885.{ref}Clay, K., Troesken, W. 2010. Did Frederick Brodie Discover the World’s First Environmental Kuznets Curve? Coal Smoke and the Rise and Fall of the London Fog, NBER Working Papers 15669. National Bureau of Economic Research. Available <a href=\"http://www.nber.org/papers/w15669\" target=\"_blank\" rel=\"noopener noreferrer\">online</a>.{/ref}</p>\n\n\n\n<p>Not only did air pollution incur a severe economic price, it also resulted in significant health costs. Air pollution deaths throughout this period rose steeply; in London, mortality from bronchitis increased from 25 deaths per 100,000 inhabitants in 1840 to 300 deaths per 100,000 in 1890. At its peak, 1-in-350 people died from bronchitis.{ref}Fouquet, R. (2011). Long run trends in energy-related external costs. Ecological Economics 70(12), 2380\u20132389. Available <a href=\"http://www.sciencedirect.com/science/article/pii/S0921800911002953\" target=\"_blank\" rel=\"noopener noreferrer\">online</a>.{/ref}</p>\n\n\n\n<p>Although London was arguably one of the worst polluted cities during this time (and often referred to as the “Big Smoke”), many other industrial cities across Great Britain (and indeed across other nations) experienced similar air pollution problems. In the photograph below, we see pollution in Widnes, an industrial town close to Liverpool, in the late 19th century.</p>\n\n\n\n<div class=\"wp-block-columns is-style-sticky-right\">\n<div class=\"wp-block-column\">\n<h6>Air pollution in Widnes, late 19th century{ref}Hardie, D. W. F., A History of the Chemical Industry in Widnes, Imperial Chemical Industries Limited, 1950. Available <a href=\"https://commons.wikimedia.org/wiki/File:Widnes_Smoke.jpg\" target=\"_blank\" rel=\"noopener noreferrer\">online</a>.{/ref}</h6>\n\n\n\n<div class=\"wp-block-image\"><figure class=\"aligncenter\"><img loading=\"lazy\" width=\"750\" height=\"424\" src=\"https://ourworldindata.org/app/uploads/2017/06/1024px-Widnes_Smoke-750x424.jpg\" alt=\"\" class=\"wp-image-12032\" srcset=\"https://owid.cloud/app/uploads/2017/06/1024px-Widnes_Smoke-750x424.jpg 750w, https://owid.cloud/app/uploads/2017/06/1024px-Widnes_Smoke-150x85.jpg 150w, https://owid.cloud/app/uploads/2017/06/1024px-Widnes_Smoke-400x226.jpg 400w, https://owid.cloud/app/uploads/2017/06/1024px-Widnes_Smoke-768x434.jpg 768w, https://owid.cloud/app/uploads/2017/06/1024px-Widnes_Smoke.jpg 1024w\" sizes=\"(max-width: 750px) 100vw, 750px\" /></figure></div>\n</div>\n\n\n\n<div class=\"wp-block-column\"></div>\n</div>\n\n\n\n<h3>London vs. today’s developing cities</h3>\n\n\n\n<p class=\"has-text-align-left\">From our first chart, we see that concentrations of suspended particulate matter (SPM) reached up to 623 micrograms per cubic metre. This figure will be meaningless to most without proper context. Let’s therefore compare historic London concentrations to those experienced in recent years in New Delhi\u2014one of the world’s <a href=\"https://www.theguardian.com/cities/datablog/2017/feb/13/most-polluted-cities-world-listed-region\" target=\"_blank\" rel=\"noopener noreferrer\">most polluted cities</a> today.</p>\n\n\n\n<p>In the first chart above, we can add SPM trends for Delhi from the later 1990’s to 2010 using the ‘add city’ button.{ref}Note that these figures are sourced from the Government of India’s Economic Survey of Delhi (2012-13). From 2010 onwards, the government provides a further breakdown to its air pollution measurements based on particle size categories, and typically does not report on total SPM. As such, comparable post-2010 data is not available.{/ref}</p>\n\n\n\n<p>What we see is that concentrations in Delhi range from around 450 to 500 micrograms per cubic metre. This is extremely high, but remains lower than peak concentrations in London during its rapid industrialization. It is wrong to assume that today’s major developing cities\u2014such as Delhi, Beijing, Jakarta, Karachi\u2014are experiencing unprecedented levels of air pollution. It’s likely that many of today’s high-income cities have gone through similar periods of high (or higher) pollution levels. Perhaps what differentiates today’s transitioning cities is the population sizes which inhabit them; exposure to such pollution undoubtedly leads to <a href=\"https://ourworldindata.org/air-pollution-post\">high mortality figures in absolute terms</a>.{ref}The absolute number of people dying prematurely from air pollution impacts has been increasing; this is despite an overall decline in the death rate (measured as deaths per 100,000 individuals) across the majority of countries in recent decades. The reason absolute numbers of deaths are increasing despite falling death rates can be attributed to population and demographic factors: population growth (and the additional impact of an aging population) has been outpacing the rate of reduction in death rates. Overall, this leads to an increase in deaths in absolute terms.{/ref}</p>\n\n\n\n<p>If we see air pollution as a by-product of <a href=\"https://ourworldindata.org/economic-growth\">economic and industrial development</a>, an appropriate comparison would be based on levels of prosperity, rather than versus time. In the chart below we have plotted the same trends in SPM (on the y-axis) for London and Delhi, but now map these levels relative to gross domestic product (GDP) per capita (on the x-axis). These GDP per capita figures are adjusted for inflation and <a href=\"https://ourworldindata.org/what-are-ppps\">expressed in international dollars</a> to reflect differences in living costs.</p>\n\n\n\n<p>Interestingly, if we observe the evolution of these trends with time, we see that at a given level of GDP per capita, Delhi’s air pollution levels have, and continue to, follow a similar pathway to that of London in the 19th century.</p>\n\n\n\n<p>But the often-forgotten history of air pollution in today’s rich countries offers an important lesson about what is possible for world regions with lower levels of prosperity today. After air pollution worsens at the initial stages of development it declines at later stages and can reach historically low levels.</p>\n\n\n\n<p>The key for Delhi and other transitioning cities will therefore be to continue shifting rightwards (increasing GDP per capita), but to try to peak below London’s 19th century pathway. If they can achieve this, then they will have succeeded in developing in a cleaner way than today’s high income cities.</p>\n\n\n\n<p><iframe loading=\"lazy\" style=\"width: 100%; height: 600px; border: 0px none;\" src=\"https://ourworldindata.org/grapher/air-pollution-vs-gdp-per-capita?time=1700..2015\" width=\"300\" height=\"150\"></iframe></p>\n", "protected": false }, "excerpt": { "rendered": "", "protected": false }, "date_gmt": "2017-06-20T08:51:42", "modified": "2023-10-11T10:49:59", "template": "", "categories": [ 82, 1 ], "ping_status": "closed", "authors_name": [ "Hannah Ritchie" ], "modified_gmt": "2023-10-11T09:49:59", "comment_status": "closed", "featured_media": 12036, "featured_media_paths": { "thumbnail": "/app/uploads/2017/06/air-pollution-london-vs-delhi-150x106.png", "medium_large": "/app/uploads/2017/06/air-pollution-london-vs-delhi-768x544.png" } } |