Acid Rain
By: Jon • Research Paper • 1,306 Words • May 4, 2010 • 1,370 Views
Acid Rain
Acid Rain is caused by pollution containing sulfur dioxide, nitrogen oxide, and ozone that is released into the air. These chemicals are absorbed into clouds and results in Acid Presipitation ( Acid Rain, Acid Snow, Acid Hail, Acid Sleet ). When the chemicals aren't absorbed into the clouds, they can drift for miles and fall to the ground, resulting in Acid Deposition, or dry deposition.
When Acid Rain falls into water it is mixed in with the normal water and causes the pH of the entire body to be raised. Measurments on the pH scale, rise greatly; a lake with a pH of 4 is ten times as acidic as a lake with a pH of 5, and a lake with a pH of 3 is 100 times as acidic, After many rain falls of Acid rain, the pH of a normal lake would go from 5.8 to 4.
Acid Rain has been known to reach the acidity of pH 2, ( battery acid has a pH if 1 ) this is a drastic change, as normal rain is average pH 5.2. (Brown, 1999)
Acid Rain can dissolve limestone and chalk, and corrodes outdoor structures. Statues and monuments that are left unprotected .
Acid Rain reacts to different types of soil and rocks in two ways:
1) Acid rain will dissolve alkaline rocks and soil, or will neutralize the alkalinity.
2) Acid rain will increase the acidity of already acidic rocks and soil such as granite, or the soil which results comes from corroded granite.
Acidic chemicals, and alkaline chemicals react to each other by reducing the alkalinity or acidity of each other. Which ever has the strongest pH level, usually will neutralize or reduce the pH of the other, but after the reaction is complete both substances have undoubtably changed. Their pH moved closer to neutral ( pH 7 ). This led to the use of Salting.
Salting ( dropping salt, chalk, or limestone into lakes and streams ) is a done to reduce the acidity of the water, and neutralize it reverse the effects of the acid rain. This involves tones of salt and an Airplane with a bombay. This is only a temporary solution because putting salt into the water will not stop the acid rain from coming, it just neutralizes what is already there. (Sheets,1998)
There have been many attempts to reduce the production of acid rain. In order to make this attempt; the emission of sulfur dioxide must be reduced. One way of doing this was by passing the Clean Air Act. The 1990 Clean Air Act's sulfur dioxide reduction program, will complement health-based sulfur dioxide pollution limits already in place to protect the public and the environment from both nearby and distant sources of sulfur dioxide.
The law sets up a market-based system designed to lower sulfur dioxide pollution levels. Beginning in the year 2000, annual releases of sulfur dioxide will be about forty percent lower than the 1980 levels. Reducing sulfur dioxide releases should cause a major reduction in acid rain. The reduction is accomplished in two phases.
Phase 1 of the program went into effect January 1, 1995.4 Big coal-burning boilers in one hundred and ten power plants in twenty-one Midwest, Appalachian, Southeastern and Northeastern states will have to reduce the release of sulfur dioxide and nitrogen oxide omissions. As a result of Phase I, acid rain concentrations have lowered by twenty five percent.
In 2000, Phase 2 of the acid rain program goes into effect, reducing the sulfur dioxide released from the big coal-burning power plants even more. They will require them to install systems that monitor emissions in order to track progress. (Smith, 1998)
A manufacturer must consider proximity to transportation routes and the location of both the source of raw materials and the market for the product. The raw materials have to be transported to the plant, and the final product must be transported to the customer or distributor. Economic pros and cons must also be thought about. For example, must sulfuric plants are located near the market because it costs more to transport sulfuric acid than the main raw materials, sulfur. Elaborate commission proof container are required for the transportation of sulfuric acid while sulfur can be much more easily transported by truck or railway car.
For a sulfuric acid plant to operate, the plant must employ chemists, technicians, administrators, computer operators, and people in sales and marketing. A large number of workers will also be required for the daily operation of the plant. A work force of this diversity is therefore likely to be found only near major centres of population.
Energy Demands Large amounts of energy will also be required for the production of many industrial chemicals. Thus, proximity to a plentiful supply of energy is often a determining