Impact of Aviation on the Global Atmopherer.Dissertation ProposalEssay Preview: Impact of Aviation on the Global Atmopherer.Dissertation ProposalReport this essayThe air travel accounts for almost 11% of Europes GDP and 24 million jobs. Air travel is the most popular mode of travel for both UK residents travelling abroad and for overseas residents visiting the UK. In 2005, UK residents made a record 53.6 million visits by air, representing almost four-fifths of all visits abroad (Friends of The Earth, 2006). The aviation industry currently faces a lot of impediments due to growing impacts of climate change, local air quality, surface access conjunction and noise.
This report will elucidate the impact of aviation on global warming and how it needs to blow the trumpet even louder to highlight the advances it has made to combat against climate change.
Some of the gases in our atmosphere such as carbon dioxide, trap heat from the sun reflecting of the earths surface, keeping the earth warm. This is called natural green house gas effect. However human activities such as burning of fossil fuels are increasing the concentration of these gases in the atmosphere. These accidental gases are enhancing the green house effect which I know as global warming. The major green house gases include carbon dioxide, methane, nitrogen and water vapour.
Air travel is the worlds fastest growing source of green house gas like Co2, which contributes to climate change. Globally the worlds 16,000 commercial jet aircraft more than 600 million tonnes of Co2. The huge increase in aircraft pollution is largely due the rapid growth in air traffic which has been expanding at nearly two and a half times average economic growth rate since 1960.
The aviation industry plays an important role in the UK economy. The demand for air travel has quadrupled over the last 25 years ,driven by falling real prices and rising incomes. For example the number of passengers travelling via UK airports has increased by 280% since 1975, while the volumes of freight handled by the UK airports have risen over by 210%. This compares an increase in UK gross domestic product (GDP) of around 60% over the same period.
According to survey conducted by newquay , apart form being lot quicker the emissions produced by air travel can significantly less when travelling by air. The study shows that an average family saloon driven at a constant speed will emit 0.06 tonnes of Co2 over the 266 miles to Newquay; with congestion in peak periods or during busy holiday time this will rise to nearly 0.1 tonnes. If one person is in the car , this equates to 0.06 – 0.1 tonnes of co2 per person being emitted for the one way journey ,significantly higher than for air travel,or if there are two people in the car -0.03-0.05 tonnes of co2 similar to the average for air travel. A one-way flight in a B737-400 would generate 5.8 tonnes of Co2; at 100% seat occupancy this equates to 0.042 tonnes of Co2 person, at 75% seat occupancy 0.055 tonnes of Co2 per person.
Theoretical ReviewTransport first became a recognized as a significant source of air pollution after the substantial problems of smog from coal combustion had been mostly resolved in the industrialized cities of Western European and North American. Since then, pollution from road, air, rail and water transport have been more significantly responsible for acid deposition, ozone depletion and climate change. Most recently, road traffic exhaust emissions have been the cause of the bulk of concern about the effects of urban air quality on human health and troposphere ozone production (Colvile et al, 2001) however, due to the continued growth in air travel , there is a rising concern about the impact of aircraft emissions on the environment.
Two of the ways in which air travel affects climate are the emission of carbon dioxide and the creation of high-altitude contrails. Currently the scientific and policy literature on aviation and climate change is subject to frequent, significant revision and alterations due to a rapidly increasing and developing knowledge base and debate topics (Upham & Jakubowicz, 2007). However, it is well understood that the combustion processes of hydrocarbons in air generates carbon dioxide (CO2), water vapor (H2O), sulfur oxides (SOx), and nitric oxide (NO) and nitrogen dioxide (NO2) (jointly termed nitrogen oxides (NOx)). As a result of incomplete combustion of fuels, additional by products such as carbon monoxide (CO), unburned hydrocarbons (HC), and particulate matter (PM) are also formed. Many of these emissions have health and climate impacts on both a local and global level. (Jamin et al, 2004)
Globally the environmental impact of aircraft largely results from two major sources, the emissions of greenhouse gases (mainly CO2, HC, NO2) and the creation of high-altitude water vapor resulting in the formation of contrails. Contrails are created in the wake of an aircraft as the warm, moist engine exhaust gas expands and mixes with colder and drier outside air. Water droplets can be formed and these droplets rapidly freeze to form ice crystals. With enough water vapor, the amount of condensation to ice is faster than that of evaporation, and the ice crystals will grow to form visible contrails (see Schumann (1996) for a review). Contrails affect the climate by reducing solar heating during the day and radiation of heat during the night by increasing the extent to which it diffusely reflects light, therefore reducing the range between day and night temperatures.
Due to the huge projected future growth rates aviation is expected to produce, the implementation of global or at least internationally coordinated instruments for the reduction of greenhouse gas emissions are of prime importance and is going to only increase in the future.(Scheelhaase & Grimme, 2007).
A recent Intergovernmental Panel on Climate Change (IPCC) report on aviation and the global atmosphere (Intergovernmental Panel on Climate Change, 1999) estimated that in 1992 aviation accounted for 13% of CO2 emissions from all transportation sources, 2.4% of total fossil fuel emissions of CO2 (Jamin et al, 2004). This suggests that the aviation industry, although undoubtedly responsible for a large amount of global pollution, is not responsible for as large a proportion of emissions as often reported. According to the Intergovernmental Panel on Climate Change (1999), International aviation is only responsible for between 2.5% and 3% of anthropogenic carbon dioxide (CO2) emissions that are partly held responsible for climate change (Scheelhaase & Grimme, 2007).
The IPCC’s report estimated that the global air space-surface temperature (CST) was approximately 4ºC higher than the mid-latitude (NHLT) (Roth, 1999). According to a detailed report prepared by the Air Resources Board for the United States in 1986 , it was estimated that the atmosphere will be 5ºC cooler by 2012 than the mid-latitude (NHLT) (Roth, 1999).
While AirBridges states that its use of air “may reduce the risks associated with global warming” , the Air Bureau stated that:
Airbridge has had no connection to climate change.” This claim is unsupported by our data because our findings are not based on a statistical study of air pollution, so we do not find an inverse relationship between air quality and air pollution, but rather on statistical tests. We agree that a “tipping point” or positive correlation of air quality with climate change is unlikely but, if we have control subjects, we expect a similar “tipping point” (i.e., the risk of emissions from anaerobic growth from the air) over time. However, this potential correlation for air quality is not unique nor independent of our findings. As noted, air quality may vary by environmental factors as well. For example, temperature is a function of temperature, and the CO2 concentrations in the air are expected to change over different seasons, so variability in temperatures and the air temperatures may be more important than temperature for determining the effect of local circumstances.
In addition to air quality, it is important to note other factors (such as climate, as well as some environmental factors) including physical activity, age-related factors, agricultural conditions, industrial capacity, or the impact of natural sources of energy such as rainwater and coal in the United States. However, some environmental factors (e.g., rain and wind, as well as other factors related to water) may not be correlated with air quality, i.e., they may affect the environmental variables in climate change prediction by changing climate variability. For example, the climate changes in the United States over the past two decades are projected to increase the likelihood that a decrease in human population, including climate change, will occur.
In addition with other factors such as climate, it is important to note other factors (e.g., temperature, and other air pollutant effects) including physical activity, age-related factors, agricultural conditions, industrial capacity, or the impact of natural sources of energy such as rainwater and coal in the United States. However, some environmental factors may not be correlated with air quality, i.e., they may affect the environmental variables in climate change prediction by changing climate variability. For example, the climate changes in the United States over the past two decades are projected to increase the likelihood that a decrease in human population, including climate change, will occur.