Renewable Source of Energy Essay Example

and commercial uses (Johansson & Burnham, 1993).

Feasibility of Development to a Full-scale Usage at Your Manufacturing Facility or Place of Work

Feasibility study indicates that hydroelectricity obtained from water is the best source of energy for full-scale usage within our manufacturing or place of work. Furthermore, tidal power can also be developed as an alternative energy.

Although regarded as being environmentally friendly and somehow difficult and relatively expensive to develop, hydroelectric power remains to be one of the most cost-efficient means of generating renewable energy in our place (Johansson & Burnham, 1993). Regardless of the fact that these underwater wind farms are more preference, they have the likelihood of impacting sea life. This is because it is linked with other environmental concerns for instance emission of greenhouse gases as well as other air pollutants when fuel is burned, thermal pollution and generation of hazardous solid wastes which affects animals, plants and the natural ecosystem as a result of waste, water, air and land impacts (John & Tony, 2015).

Comparing Renewable Energy Costs and Benefits With its Non-Renewable Energy Counterpart

Renewable sources of energy are easily regenerated, does not pollute the environment and they are readily available everywhere hence there is no possibility of them becoming depleted in future, unlike non-renewable energy which is perishable once use (Michaelides, 2012). Equally, renewable sources of energy increase job opportunities as well as boosting economic growth. Nevertheless, renewable energy facilities usually require little maintenance as compared to conventional generators.

Their fuel which is obtained from natural and readily available resources assists in reducing the costs of operation. Because of this reason, maintenance costs incurred in installing as well as using

renewable energy is relatively cheap. This makes them cost effective and easier to produce and use (John & Tony, 2015). Hydro-Electric can be used in a manufacturing facility to reduce the gas emissions of the greenhouse.

Carbon Cycle and How it is Applied During Fossil Burning

Carbon is an element which abundant on the earth and is necessary for supporting life. The carbon cycle is typically the exchange of carbon between all the components of the earth i.e. rocks and sediments, atmosphere, oceans and rivers, and living things (Trabalka & Reichle, 1986). It is noted that this cycle involves the flow, or flow, of carbon between different earth systems.

The process or object which absorbs and stores carbon is termed as a sink although the one which releases it faster than the rate of its absorption is called a source. Photosynthesis and respiration are termed as the basis of the carbon cycle (Mongillo & Zierdt-Warshaw, 2000). Fossil fuels usually represent the carbon storage areas. The carbon which is locked in them does not cycle through the earth.

During the process of burning fossil, the stored one is released into the atmosphere in the form of carbon IV oxide. This carbon then becomes free to cycle through the earth and in return it has the ability to upset the natural balance of the carbon that is available in the atmosphere (Trabalka & Reichle, 1986). This then changes the way the carbon process occurs on the earth.

Environmental Impact of Shifting Energy

According to Samet (2008), shifting renewable energy significantly reduces the environmental effects of most technologies that utilize energy. The shift to hydro-electricity is likely to sustain the environment

because it is a clean source of energy fueled by water and thus less likely to pollute the air.

References

1. Johansson, T. B., & Burnham, L. (1993). Renewable energy: Sources for fuels and electricity. Washington, DC: Island Press. https://books.google.co.ke/booksid=40XtqVMRxOUC&printsec=frontcover&dq=Renewable+energy:+Sources+for+fuels+and+electricity&hl=en&sa=X&ved=0ahUKEwj41fbM_5TQAhWMzRoKHVcJB_IQ6AEIMzAA
2. John T & Tony W, (2015).

   Renewable Energy Resources. Taylor & Francis Presshttps://books.google.co.ke/books?id=LYMcBgAAQBAJ&pg=PR2&dq=Renewable+Energy+Resources&hl=en&sa=X&ved=0ahUKEwjbjMKl_5TQAhVCbBoKHRjJDPsQ6AEIMzAA#v=onepage&q=Renewable%20Energy%20Resources&f=false

3. Michaelides, E. (2012). Alternative energy sources.

   Heidelberg: Springer. https://books.google.co.ke/books?id=xdH4cqCMxfcC&printsec=frontcover&dq=Alternative+energy+sources.&hl=en&sa=X&redir_esc=y#v=onepage&q=Alternative%20energy%20sources.&f=false

4. Mongillo, J., & Zierdt-Warshaw, L. (2000). Encyclopedia of environmental science. Phoenix (Arizona: Oryx Press. https://books.google.co.ke/books?id=ozAN5vLbssgC&printsec=frontcover&dq=Encyclopedia+of+environmental+science&hl=en&sa=X&redir_esc=y
5. Samet, R.

   H. (2008). Long-range futures research: An application of complexity science. North Charleston, S.C: BookSurge Pub. https://books.google.co.ke/booksid=oBZ7E_yv8YgC&printsec=frontcover&dq=Long+Range+Futures+Research:+And+application+of+complexity+science.&hl=en&sa=X&redir_esc=y#v=onepage&q=Long%20Range%20Futures%20Research%3A%20And%20application%20of%20complexity%20science.&f=false

6. Trabalka, J.

   R., & Reichle, D. E. (1986). The Changing Carbon Cycle: A Global Analysis. New York, NY: Springer New York.

   https://books.google.co.ke/booksid=0OlVBgAAQBAJ&printsec=frontcover&dq=The+Changing+Carbon+Cycle:+A+Global+Analysis&hl=en&sa=X&redir_esc=y#v=onepage&q=The%20Changing%20Carbon%20Cycle%3A%20A%20Global%20Analysis&f=false