🌈Earth Systems Science Unit 12 – Climate Change & Air Pollution Impacts
Climate change and air pollution are interconnected environmental challenges with far-reaching impacts. Long-term shifts in climate patterns, primarily driven by increased greenhouse gas emissions from human activities, are altering Earth's systems and ecosystems.
Air pollutants, including particulate matter, sulfur dioxide, and nitrogen oxides, harm human health and the environment. These issues stem from various sources like transportation, industry, and agriculture, requiring comprehensive mitigation strategies and policies to address their complex effects.
Climate change refers to long-term shifts in global or regional climate patterns, primarily due to increased levels of atmospheric carbon dioxide produced by the use of fossil fuels
Greenhouse gases (GHGs) trap heat in the atmosphere, leading to global warming (carbon dioxide, methane, nitrous oxide, water vapor)
Global warming potential (GWP) measures the relative radiative effect of a given substance compared to carbon dioxide over a specified time period (usually 100 years)
Radiative forcing quantifies the difference between solar irradiance (sunlight) absorbed by the Earth and energy radiated back to space
Albedo is the measure of the reflectivity of a surface (snow and ice have high albedo, while oceans and forests have low albedo)
Anthropogenic emissions originate from human activities (burning fossil fuels, deforestation, agriculture)
Carbon cycle describes the exchange of carbon among the atmosphere, oceans, terrestrial biosphere, and geological deposits
Includes processes such as photosynthesis, respiration, decomposition, and weathering
Climate Change Basics
Earth's climate has changed throughout history due to natural factors (variations in solar activity, volcanic eruptions, changes in Earth's orbit)
However, the current warming trend is of particular significance because it is extremely likely (greater than 95% probability) to be the result of human activity since the mid-20th century
The primary driver of climate change is the greenhouse effect, which occurs when GHGs trap heat in the atmosphere
The concentration of atmospheric carbon dioxide has increased by more than 40% since pre-industrial times, primarily due to fossil fuel emissions and secondarily from net land use change emissions
Global surface temperature has risen about 1.62°F (0.9°C) since the late 19th century, with most of the warming occurring in the past 35 years
Oceans have absorbed much of this increased heat, leading to rising sea levels due to thermal expansion and melting land ice (glaciers and ice sheets)
Climate change impacts various Earth systems (hydrosphere, cryosphere, biosphere) and can lead to more frequent and intense extreme weather events (heatwaves, droughts, hurricanes)
Major Air Pollutants
Particulate matter (PM) consists of tiny particles of solid or liquid suspended in the air (dust, soot, smoke)
PM2.5 refers to fine inhalable particles with diameters 2.5 micrometers and smaller
PM10 includes inhalable particles with diameters 10 micrometers and smaller
Sulfur dioxide (SO2) is a colorless, reactive gas produced by burning sulfur-containing fuels (coal, oil) and industrial processes (metal smelting)
Nitrogen oxides (NOx) are highly reactive gases formed during combustion processes (vehicle emissions, power plants)
Include nitric oxide (NO) and nitrogen dioxide (NO2)
Ground-level ozone (O3) is a secondary pollutant formed when NOx and volatile organic compounds (VOCs) react in the presence of sunlight
Ozone in the stratosphere is beneficial as it absorbs harmful ultraviolet (UV) radiation
Carbon monoxide (CO) is a colorless, odorless gas produced by incomplete combustion of carbon-containing fuels (vehicle exhaust, industrial processes)
Lead (Pb) is a toxic heavy metal that can be released into the air from industrial sources (metal processing) and leaded gasoline (now banned in many countries)
Volatile organic compounds (VOCs) are emitted as gases from certain solids or liquids and can have short- and long-term adverse health effects (benzene, formaldehyde)
Sources of Emissions
Transportation sector contributes significantly to air pollution and GHG emissions (cars, trucks, ships, airplanes)
Burning of fossil fuels in internal combustion engines releases CO2, NOx, PM, and VOCs
Electricity generation from coal-fired power plants emits CO2, SO2, NOx, and PM
Natural gas power plants emit less CO2 and negligible amounts of SO2 and PM compared to coal
Industrial processes (manufacturing, mining, oil and gas extraction) can release a variety of pollutants (PM, SO2, NOx, VOCs, heavy metals)
Agricultural activities contribute to air pollution and GHG emissions (livestock farming, fertilizer use, rice cultivation)
Livestock farming releases methane (CH4) from enteric fermentation and manure management
Fertilizer application emits nitrous oxide (N2O) from microbial processes in the soil
Waste management practices (landfills, wastewater treatment) can emit methane and other GHGs
Residential and commercial buildings contribute to emissions through energy use for heating, cooling, and electricity consumption
Deforestation and land use changes release stored carbon into the atmosphere and reduce carbon sequestration capacity
Environmental Impacts
Climate change leads to rising sea levels due to thermal expansion of oceans and melting of land ice (glaciers, ice sheets)
Threatens coastal communities and infrastructure, increases risk of flooding and erosion
Warmer temperatures alter precipitation patterns, leading to more frequent and intense droughts in some regions and heavy rainfall and flooding in others
Ocean acidification occurs as oceans absorb excess atmospheric CO2, lowering the pH of seawater
Biodiversity loss and ecosystem degradation result from changing climate patterns, habitat loss, and species migration
Some species may adapt or shift their ranges, while others face increased risk of extinction
Air pollution can lead to acid rain when SO2 and NOx react with water and oxygen in the atmosphere
Acid rain damages forests, crops, and aquatic ecosystems, and accelerates the deterioration of buildings and monuments
Ground-level ozone and PM can harm vegetation by reducing photosynthesis and growth rates
Ozone damage to crops can lead to reduced agricultural yields
Deposition of nitrogen and sulfur compounds from air pollution can lead to eutrophication of water bodies
Excess nutrients stimulate algal blooms, depleting oxygen levels and creating "dead zones" in aquatic ecosystems
Human Health Effects
Air pollution exposure is linked to respiratory diseases (asthma, chronic obstructive pulmonary disease)
PM and ozone can irritate the airways, aggravate existing conditions, and reduce lung function
Cardiovascular diseases (heart attacks, strokes) are associated with long-term exposure to PM and other pollutants
PM can enter the bloodstream and cause inflammation, increasing the risk of blood clots and atherosclerosis
Certain air pollutants (PM, ozone, NO2) can exacerbate allergies and increase the risk of respiratory infections
Exposure to air pollution during pregnancy has been linked to adverse birth outcomes (low birth weight, preterm delivery)
Long-term exposure to air pollution may contribute to the development of neurodegenerative diseases (Alzheimer's, Parkinson's)
Climate change can impact human health through various pathways (heat stress, vector-borne diseases, food and water insecurity)
Warmer temperatures can lead to heat-related illnesses (heat exhaustion, heat stroke) and increase the risk of cardiovascular and respiratory mortality
Changing climate patterns can alter the distribution and transmission of vector-borne diseases (malaria, dengue fever)
Measurement and Monitoring
Air quality monitoring networks measure concentrations of criteria pollutants (PM, SO2, NO2, O3, CO, Pb)
Data is used to assess compliance with air quality standards and inform public health advisories
Satellite remote sensing provides global coverage of air pollutants and GHG concentrations
Instruments measure backscattered solar radiation or thermal infrared emission to derive atmospheric composition
Ground-based monitoring stations directly measure pollutant concentrations using various techniques (chemiluminescence, UV photometry, beta attenuation)
Atmospheric dispersion models simulate the transport, transformation, and deposition of pollutants based on emissions data and meteorological conditions
Greenhouse gas inventories estimate anthropogenic emissions by sector and source category
Follow standardized methodologies developed by the Intergovernmental Panel on Climate Change (IPCC)
Climate models project future changes in temperature, precipitation, and other variables based on different emission scenarios and assumptions about socioeconomic development
Health impact assessments estimate the burden of disease attributable to air pollution exposure using epidemiological studies and exposure-response functions
Mitigation Strategies and Policies
Transitioning to clean energy sources (renewable energy, nuclear power) can reduce GHG emissions from the electricity sector
Renewable energy sources include solar, wind, hydro, geothermal, and biomass
Improving energy efficiency in buildings, industry, and transportation can reduce energy demand and associated emissions
Includes measures such as building insulation, energy-efficient appliances, and fuel-efficient vehicles
Implementing carbon pricing mechanisms (carbon taxes, cap-and-trade systems) can create economic incentives to reduce emissions
Puts a price on carbon emissions, encouraging companies and individuals to adopt low-carbon technologies and practices
Promoting sustainable transportation (public transit, electric vehicles, active transport) can reduce emissions from the transportation sector
Adopting sustainable land management practices (reforestation, afforestation, reduced deforestation) can enhance carbon sequestration and reduce emissions from land use change
Implementing air quality regulations and standards can limit emissions of criteria pollutants from industrial sources and vehicles
Includes emission control technologies (scrubbers, catalytic converters) and fuel quality standards
Encouraging sustainable consumption and production patterns can reduce the environmental footprint of goods and services
Includes measures such as eco-labeling, extended producer responsibility, and circular economy principles
Enhancing public awareness and education can promote individual actions to reduce emissions and support climate-friendly policies