Describe the phenomenon that causes the wind belts to shift. Show how it affects a region’s climate as well. (Answer in 250 words)
Ozone (03) is a highly reactive gas composed of three oxygen atoms. It is both a natural and a man-made product that occurs in the Earth's upper atmosphere (stratosphere) and lower atmosphere oxygen (troposphere). Depending on where it is in the atmosphere, ozone affects life on Earth in either goodRead more
Ozone (03) is a highly reactive gas composed of three oxygen atoms. It is both a natural and a man-made product that occurs in the Earth’s upper atmosphere (stratosphere) and lower atmosphere oxygen (troposphere). Depending on where it is in the atmosphere, ozone affects life on Earth in either good or bad ways. Formation of tropospheric and stratospheric ozone Tropospheric or ground-level ozone is formed primarily from photochemical reactions between two major classes of air pollutants, volatile organic compounds (VOCs) and nitrogen oxides (NOx). NOx and VOC break apart in the presence of intense sunlight and recombine into new structures, creating ozone. It is created by human activities as emissions from industrial facilities and electric utilities, motor vehicle exhaust, gasoline vapor, and chemical solvents are some of the major sources of NOx and VOC. On the other hand, stratospheric ozone is formed naturally through the interaction of solar ultraviolet (UV) radiation with molecular oxygen (02). Solar ultraviolet radiation breaks apart one oxygen molecule (02) to produce two oxygen atoms (20) and each of these highly reactive atoms combines with an oxygen molecule to produce an ozone molecule (03). These reactions occur continually whenever solar ultraviolet radiation is present in the stratosphere. Role of tropospheric and stratospheric ozone The tropospheric ozone or bad ozone can trigger a variety of health problems including chest pain, coughing, and throat irritation. It is also a major component of urban smog, which can worsen bronchitis and emphysema, trigger asthma, and permanently damage lung tissue. Further, bad ozone also damages vegetation and ecosystems as it leads to reduced agricultural crop and commercial forest yields, reduced growth and survivability of tree seedlings, and increased susceptibility to diseases, pests, and other stresses such as harsh weather. Whereas, the stratospheric ozone absorbs a portion of UV (Ultra Violet) light called UVB from the sun, preventing it from reaching the planet’s surface. Thus, it protects from many harmful effects, including skin cancers, cataracts, and harm to some crops and marine life. But this good ozone is gradually being destroyed by man-made chemicals referred to as ozone-depleting substances (ODS), including chlorofluorocarbons (CFCs), hydrochlorofluorocarbons (HCFCs), etc.
Strategies to prevent the formation of tropospheric ozone.
- Fossil fuels & transport sector
- Vapor recovery nozzles at the gasoline pumps to reduce refueling emissions.
- Cleaner burning gasoline is reformulated through catalytic convertors to reduce VOC, NOx, etc.
- Strict NOx emission limits for power plants and industrial combustion sources.
- Agriculture sector:
- Apply intermittent aeration of continuously flooded rice fields.
- Introduce selective breeding to reduce emission intensity and increase production.
- Waste management
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- Separate and treat biodegradable municipal waste, and turn it into compost or bioenergy.
- Upgrade wastewater treatment with gas recovery and overflow control.
- Better Monitoring of Ozone mitigation initiatives such as that of long-range Transboundary Air Pollution through the implementation of the Gothenburg protocol and effective forecasting through SAFAR (System of Air Quality and Weather Forecasting).
The Government has further taken initiatives such as the National Clean Air Programme (NCAP), Graded Response Action Plan (GRAP), etc. to check ozone pollution and improve air quality. There is a need for the effective implementation of multi-faceted programs to cut NOx and VOC emissions from vehicles, industrial facilities, and electric utilities. Voluntary programs may also be started to encourage the communities to adopt practices, such as carpooling, to reduce harmful emissions.
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Jet streams play a significant role in altering the global and regional climate.
The relative position of the Earth with respect to the sun changes within a year due to Earth's revolution. Further, due to the inclination of the Earth on its axis, there are differences in the heating of the continents and oceans, and as a result, the pressure conditions in January and July vary gRead more
The relative position of the Earth with respect to the sun changes within a year due to Earth’s revolution. Further, due to the inclination of the Earth on its axis, there are differences in the heating of the continents and oceans, and as a result, the pressure conditions in January and July vary greatly. This consequently results in the shifting of the wind belts.
Shifting of pressure and wind belts:
These seasonal changes in the relative positions of the wind belts introduce the following typical climatic conditions:
(i) The Mediterranean climatic regions are found in the western parts of the continents within the latitudinal zone of 30°-45° in both hemispheres. The Sub-Tropical High-Pressure Belts extending between 30°-35° latitudes are characterized by dry trade winds during the summer season and anti-cyclonic conditions. This belt extends up to 40° latitudes in the Northern hemisphere at the time of summer solstice and in the Southern hemisphere at the time of winter solstice. Thus, the western parts of the continents within the zone of 30°-40° latitudes do not receive rainfall during the summer season. On the other hand, the Sub-Tropical Belt shifts towards the Equator at the time of winter solstice in the Northern hemisphere and at the time of summer solstice in the Southern hemisphere. Consequently, the zone is characterized by the Westerlies, which lead to precipitation during the winter season. The Mediterranean type of climate is thus characterized by dry summers and wet winters. (ii) The regions lying between 60°-70° latitudes are characterized by two types of winds in a year. With the northward migration of the sun at the time of summer solstice, the Polar Easterlies are weakened because the Westerlies extend over these areas due to the northward shifting of Sub-Polar Low-Pressure Belts. The situation is reversed at the time of winter solstice when there is southward migration of the sun. The Polar Easterlies are re-established between 60°-70°N because of the shifting of the belt of the Westerlies southward. Consequently, it creates a climate characterized by wet summers through the Westerlies and associated cyclones and dry winters due to Polar Easterlies. (iii) Monsoon climate is also the result of the shifting of pressure and wind belts. Due to the northward migration of the sun in the Northern hemisphere at the time of summer solstice, the North Inter-Tropical Convergence Zone (NITCZ) is extended up to 30°N latitude over the Indian subcontinent, Southeast Asia, and parts of Africa. Thus, the Equatorial Westerlies are also extended over the aforesaid regions, which become the southwest or summer monsoons. These southwest monsoon winds bring much rain because they come from over the ocean and are associated with tropical cyclones. The NITCZ is withdrawn from the Indian subcontinent and Southeast Asia because of the southward shifting of pressure and wind belts due to the southward migration of the sun at the time of winter solstice. Thus, north-east trades are re-established which leads to the north-east or winter monsoons. Since they come from over the lands, they are dry.
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