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Environmental engineering is one of the most popular, complex and fast growing disciplines in engineering. The scope of environment includes issues from public health, aesthetics, and impact of all development activities, pollution control legislation, standards, regulations, guidelines and their enforcement. Traditionally the application of engineering principles for the protection and enhancement of the quality of environment and protection of public health was called as sanitary engineering or public health engineering. Around 1968 this was changed to environmental engineering.

For conceiving environmental engineering, one has to consider the definition of engineering itself. Engineering may be defined as the application, under limits of scientific principles for the planning, design, execution, operation and maintenance of structures, equipment and systems for the development and benefit of the society. Here the word benefit is more important than the development. The so-called development in some cases may not be in real benefit of the society.

The environmental engineer plans, designs, executes, operates and maintains the water, wastewater and solid waste management plants. Clean, bacteriologically safe, potable drinking water protects and enhances public health. Liquid and solid waste management is a necessary step for healthy living. They also deal with air pollution control. The resulting pure cleaner air is conducive to people’s good health and prevents the building and other materials from the harmful effects of air pollution. The environmental engineer cares for the energy requirements of the society and the ways and means to protect the environment against the various pollutions created through the production and consumption of various goods and comfort conditions. It is the duty of environment engineer to assess the environmental impacts of the various development and other activities. In general one has to work to have sustainable and holistic development. Of course there are always constraints of resources, knowledge, human nature, social and racial considerations that limit the achievement of these goals.

Therefore the environmental engineering is defined as the application of scientific and engineering principles, under limits, for the protection and enhancement of the environment that includes the biotic and abiotic both components.

The environment exists in dynamic equilibrium of its biotic (living) and abiotic (non-living) elements. The solar energy induced photosynthesis synthesizes the carbon as the plant tissue and we get matter in various forms from the trees. The carnivores, humans and animals consume the edible matter. They convert it into the energy required to sustain their lives. Their excreta comes near to the nature and the natural scavengers, bacteria and others convert it into inorganic matter like nutrients due to the biological decomposition. The roots of the plants, to form the edible matter again, extract these nutrients. Like this the nutrient cycle, material cycle, energy cycle and other cycles like hydrological cycle keep on existing until there is a great shock given by the human beings.

“Nature has enough for satisfying everybody’s need but not for anybody’s greed”. Human beings have lost their natural wisdom in want of power to overcome the nature. Since mid century the word has lost nearly one fifth of the topsoil from its cropland, a fifth of its tropical rainforests and animal species. Rapid industrialization and urbanization has increased carbon dioxide levels to the
point where global climate is being affected. The protective ozone shield is being depleted because of the chlorofluorocarbons. The forest, which is a complete ecosystem, is being converted into dead forests. The biodiversity is reducing everywhere in the world.

Biodiversity gives strength to the ecosystem against crisis. Only a well-diversified community can sustain against the extreme conditions. In quest of comfort conditions and well-secured life we have adopted a system, which is completely away from nature. We have made computers for paper less office work but the energy in making and running the computers is more than the savings made.

Of course there are other advantages of computers in computation, up keeping of data etc. But the materials used in making the computer and the disposal of the obsolete ones are drastically against the environment.

The quest of more and more comfort has fetched us far away from natural environment. The input of energy in building sector is increasing day by day. The requirements of both heating and cooling are becoming more and more energy exhaustive. At present the energy requirement in whole world is mainly met by fossil fuels. Nature has created the coal and petroleum in millions of years and we have exhausted them in hundreds of years. In the last 300 years we have consumed most of the coal and almost all of the petroleum products.

Out of the 1,30,000 MW installed capacity of electricity production in India about 66% is by fossil fuels (coal+ petroleum products), 24% by hydropower, 4% by nuclear means and only 6% by renewable energy resources like solar, wind, biomass including small hydropower plants. Still there is a very large potential of renewable energy resources unutilized but the present availability of fossil fuels and the present high cost of electricity production through R.E.S. has restrained their share to only 6%. With the advancement of technology and scarcity of fossil fuels the cost of RES will come down and there share shall increase, but is it the sustainable development? In modern context the idea of sustainable development immerged in the Earth Summit at Rio-De-Janeiro in June 1992 that let us plan a development in which the generations to come, may not become deprived of the resources which we are using today. To achieve this aim we have to control our present rate of consumption of the available resources like the fossil fuels, ground water and conserve the bio diversity and the natural cycles like the hydrological cycle.

While considering the production, consumption or utilization we have also to consider the other part that is pollution. Mixing of unwanted hazardous elements in anything is known as pollution, like mixing of sewage in fresh body of water, mixing of gases, like oxides of nitrogen, oxides of sulphur etc. in the air, increase of noise level etc. Actually the present trend of living is a serious cause of creating pollution in all spheres of life. Today the prosperity, wealth or living standard of a country is measured in terms of the per capita electricity consumption per year. That way India with its per capita consumption of 350 Kwh per year is considered far behind the U.S. which has around 20 times more than this. The advancement of a society is measured in terms of the measures of comfort like air conditioners, or conveyance like bigger and bigger expensive luxury cars. Taller buildings, more and more precious artificial fabric and so on. Production and maintenance of all these has created so much land, water and noise pollution that has overcome the advantages of all these so called advancements. Thus the challenging aspect of environmental engineering is to make balance between the rapid changes in the field of science, technology, health etc. and the very existence of life. Though environmentalism or the environmental consciousness is ancient the environmentalism became an organized force only in 1960s. It started with the publication of the book Silent Spring by Rachel Carson on the pesticide DDT in 1962. Actually the exponential growth of population and the worldwide consumerism imposed a great load on earth’s natural resources and waste management systems.

This text aims at the fundamental, primary knowledge for every one who has a concern about environment. The chapters have been designed to quench the thrust of knowledge of a person, let it be a scientist, an engineer or any one who is concerned about protection of environment and thus a well wisher of society.

This book has been written after gaining 10 years experience of working in the public health engineering department of Rajasthan and 20 years experience of teaching civil engineering students, subjects like environmental engineering, ecology and environmental dynamics, solid waste management etc. Recently environmental engineering has been introduced as a primary course common to first year students of all branches who opt for it. This text is on basic environmental engineering that covers the syllabus of first year semester scheme of the Rajasthan Technical University and other universities. Some portion of the martial presented in this book has bean derived from the work of others, their contribution is greatly ackoweldged. The recommendation of manual of water supply and treatment, manual on Sewerage and Sewage Treatment and manual on Solid Waste Management prepared by the Central public Health and Environmental Engineering organization, Government of India, Ministry of urban development have been closely followed.

I acknowledge my debts to my parents for their blessings, my wife Bharati for her constant support, my daughter Ruchira for her help on computer, my son Saurabh and daughter-in law Surabhi for encouragement. I express my deep sense of gratitude to my teacher Prof. Damodar Sharma, Vice chancellor Rajasthan Technical University, Kota for being a constant source of inspiration for me. I thank Prof. M. P. Poonia Principal Engineering College Bikaner for his valuable suggestions. I thank Dr. A. K. Mathur and other colleagues of my department for their help. I thank Mr. S. Gupta, Managing Director, New Age International Publishers, New Delhi for prompt publication.

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Research shows the next generation of Texas youth is not prepared to take on the challenges of the 21st century. Eighty percent of jobs created in the next decade will require math and science skills. However, today’s students show declining interest in the subjects, with 84 percent of middle school students saying they would rather clean their room, eat their vegetables, go to the dentist or take out the garbage than learn math or science.

This is an issue that threatens the United States’ and the state of Texas’ ability to compete in the global marketplace as a leader in innovation. Which is why Time Warner Cable has launched Connect a Million Minds, a $100 million initiative over five years to address America’s continuing decline in the areas of science, technology, engineering and math (STEM).

With launch events in Waco, San Antonio and Austin the company is kicking off the initiative by giving students opportunities for hands-on learning about science and technology in their own backyards.

Middle school students in Austin toured Darrel K. Royal-Texas Memorial Stadium to learn about the science, technology and engineering behind the 134-foot jumbotron, the recent stadium expansion and the technologically-advanced field turf.

“This initiative is all about instilling a passion in our young people for science, math, technology and engineering,” said DeLoss Dodds, Athletic Director at the University of Texas at Austin and participant in the Austin Connect a Million Minds launch.

Students from the Girls Inc. program in San Antonio attended a three-day STEM camp sponsored by Time Warner Cable that included a range of hands-on learning activities. Students learned about the chemical reaction needed to make ice cream, toured Time Warner Cable to learn the engineering behind television and participated in a variety of other tasks to grow their interest in and passion for science, technology, engineering and math.

“The more than 4.5 million students in Texas all have the potential to be the next great scientist or engineer if they receive support and opportunities,” said Jon Gary Herrera, Time Warner Cable regional vice president of communication in Texas. “This is why Time Warner Cable is dedicating its resources toward instilling in students across Texas a passion for the science and math skills that will make them the problem solvers of tomorrow.”

Students in Waco had the opportunity to learn first-hand about the future of environmentally-sensitive construction when touring the Waco Chamber of Commerce Building, the first “green” chamber building in the U.S. The group also learned about the engineering behind the city’s more-than 100-year-old suspension bridge and the television studio all while on a tour of Waco.

The city’s mayor, Virginia DuPuy, proclaimed the day Connect a Million Minds Day, stating, “As we all strive to be a positive influence in the lives of young people, the Citizens of Waco express their appreciation to Time Warner Cable for its public commitment to making a true difference in the lives of children in Waco and across Texas and the United States.”

Connect a Million Minds is intended to inspire youth to pursue STEM by connecting them to out-of-school learning opportunities in their community. Through a dedicated Web site, local video on-demand content, public service announcements and more, Time Warner Cable is raising awareness among youth and parents that the pursuit of out-of-school science, technology, engineering and math education can be fun and engaging.

ConnectAMillionMinds.com is the first-of-its-kind national aggregator of afterschool opportunities for youth in science, technology, engineering and math (STEM). This tool will provide parents in the community with a free and easy way to find fun, hands-on learning opportunities for their kids. Organizations have the ability to register their programs to help get the word out to parents and students in a simple way.

The tour of Texas will continue in the coming months with stops in El Paso, Dallas and the Rio Grande Valley.

2009 Siemens Competition Regional Winners Announced at The University of Texas at Austin; Will Move on to National Finals for Chance at $100,000 Peter Hu Wins Top Individual Prize; Sean Karson, Dan Liu and Kevin Chen Win Top Team Prize.

Research projects in the areas of materials science and mathematics scored top marks this evening, as Peter Hu of Denton, Texas and the team of Sean Karson of Winter Park, Florida, Dan Liu of Austin, Texas and Kevin Chen of Missouri City, Texas received the highest honors at the Region Two Finals of the 2009 Siemens Competition in Math, Science & Technology, the nation’s premier high school science competition.

Tonight’s winners will receive thousands of dollars in college scholarships and be invited to compete at the National Finals in New York City on December 3-7, where the winners of six regional competitions across the United States will vie for scholarships ranging from $10,000 to the top prize of $100,000. The Siemens Competition, a signature program of the Siemens Foundation, is administered by the College Board.

“These students have just earned their place among the nation’s greatest high school scientists,” said James Whaley, President of the Siemens Foundation, based in Iselin, New Jersey. “Each year, the students’ work becomes more impressive, and in a record-setting year such as this one, their achievements become even more outstanding. We are proud to welcome them into our family of Siemens Scholars and look forward to their participation at the national finals in New York City.”

The students presented their research this weekend to a panel of judges from The University of Texas at Austin, host of the Siemens Competition Region Two Finals.

Individual Winner

Peter Hu, a senior at the Texas Academy of Mathematics and Science in Denton, Texas, won the individual category and a $3,000 college scholarship for his materials science project that aimed to develop a novel and biologically compatible material for protein drug delivery. While similar delivery systems for therapeutic proteins are known in scientific literature, many of these materials were found to be carcinogenic. Mr. Hu’s research, titled Novel Thermogelling Dispersions of Polymer Nanoparticles for Controlled Drug Delivery, focused on an alternative FDA-approved material to mimic the behavior of these previous delivery systems, effectively avoiding prior toxicity issues.

“While all of the projects were very impressive today, Mr. Hu’s research was successful on many levels,” said Dr. Christopher Bielawski, Associate Professor in the Department of Chemistry and Biochemistry at The University of Texas at Austin. “This research project established a key proof of concept in the laboratory and the materials presented are poised for examination in living systems. Mr. Hu’s work is very advanced and comparable to that of a second or third year graduate student; with minimal tweaks, this research project stands an excellent chance at being published in a top-tier scientific journal and will likely make quite a splash in many scientific communities.”

Mr. Hu is a senior who aspires to one day lead a research team at a university or facility, such as the National Cancer Institute. Currently, he is the Vice President of the Junior Engineering Technical Society, and is organizing a science demonstration team in order to promote interest in math and science among elementary and middle school students. Mr. Hu is also a member of his school’s Research Organization.

Both of Mr. Hu’s parents are physicists, spurring his interest in science at a young age. In addition to his academic pursuits, Mr. Hu plays piano and violin, as well as basketball and table tennis in his free time. His mentor for this research project was Professor Liping Tang of the Department of Bioengineering at The University of Texas at Arlington.

Team Winners

Sean Karson, a senior at Trinity Prepatory High School in Winter Park, Florida; Dan Liu, a junior at the Liberal Arts and Science Academy High School in Austin, Texas; and Kevin Chen, a junior at William P. Clements High School in Sugar Land, Texas, won the team category and will share a $6,000 college scholarship for their mathematics project entitled Relating Missing and Decycling Edges in Directed Graphs. The team’s mathematics project has the potential to increase efficiency in real world networks by establishing an upper bound on the minimum number of connections that must be removed to destroy all cyclic pathways in systems like the World Wide Web and transcontinental trade routes.

“The team’s work was truly impressive in that it focused on a topic in pure mathematics,” said Dr. Haskell Rosenthal, John T. Stuart III Centennial Professor Emeritus in Mathematics at The University of Texas at Austin. “With new and delicate techniques, they have advanced the infrastructure and knowledge of graph theory by providing better bounds, which is of fundamental importance to the mathematics community. Their depth of knowledge was remarkable, and their work was on the same level of that of a Ph.D.”

Mr. Karson is a senior who has received Excellence Awards for Honors Computer Programming C++, Graphics I, Honors Chemistry, Honors Precalculus, AP JAVA and AP Chemistry. He has also received the Rensselaer Polytechnic Institute Math & Science Award, and is recognized as a National Merit Semifinalist. Mr. Karson is Captain of the Quiz Bowl Team, President of Mu Alpha Theta, a member of the Spanish Honor Society and the National Honor Society and volunteers for the Center of Math, Arts and Science Achievement. He has also received the Varsity Baseball Coach’s Award and the Most Valuable Defensive Player Award, and has been the starting third baseman on the Varsity Baseball Team since his sophomore year. Mr. Karson has also leveraged his love of puzzles to create a club called Rubik’s Revenge, aimed to teach middle school students how to solve Rubik’s Cubes.

Mr. Liu is a junior who aspires to one day become a computer or electronics engineer or programmer. He is currently Vice President of the InvenTeams Club, Co-Director of his school’s Math Team, and a member of the Liberal Arts and Science Academy’s (LASA) National Honor Society Chapter. Mr. Liu is also a part of the LASA Camerata Orchestra and Science Olympiad Team. He is a part of the Circle C Swim Team, and also plays badminton and ping-pong.

Mr. Chen is a junior and is a member of his school’s Mu Alpha Theta, Junior Engineering Technical Society and Computer Science Team.  He is also an active volunteer at a local middle school Math Club. Mr. Chen’s dad is a computer engineer and has taught mathematics and physics in the past, playing a large role in sparking his interest in math when he was young. His mother is also very encouraging and supportive of his passion for math and science, helping to foster his current academic interests. He enjoys practicing piano, playing tennis and programming games in his free time.

The team’s mentor was Dr. Jian Shen, Professor of Mathematics at Texas State University in San Marcos, Texas.

Regional Finalists
Regional Finalists each received a $1,000 scholarship.

Regional Finalists in the individual category were:
–  Sai Achi, Texas Academy of Mathematics and Science, Denton, TX
–  Somak Das, Texas Academy of Mathematics and Science, Denton, TX
–  Prianka Ghoshal, Westlake High School, Austin, TX

–  Sahil Khetpal, Texas Academy of Mathematics and Science, Denton, TX

Regional Finalists in the team category were:
–  Fayen Bastani and Jonathan Lin, Jasper High School, Plano, TX
–  Sumit Gogia and Patrick Kim, The Science Academy of South Texas,
Mercedes, TX; and Vincent Yu, Sha Tin College, Sha Tin, Hong Kong
–  Sunil Pai, The Kinkaid School, Houston TX; and Aneesh Sampath, Ward
Melville High School, East Setauket, NY

–  Tianjiao (Tom) Zhang and Liang Gu, Bellaire High School, Bellaire, TX

The Siemens Competition

The Siemens Competition was launched in 1998 to recognize America’s best and brightest math and science students. In another record-setting year, 2,151 students registered to enter the Siemens Competition in Math, Science and Technology in 2009 – more than ever before – for a total of 1,348 project submissions – a 14% increase in project submissions over 2008 figures and more than a 12% increase in the number of registrations.

Entries are judged at the regional level by esteemed scientists at six leading research universities which host the regional competitions: California Institute of Technology; Carnegie Mellon University; Georgia Institute of Technology; Massachusetts Institute of Technology; University of Notre Dame; and The University of Texas at Austin.

Winners of the regional events are invited to compete at the National Finals at New York University in New York City, December 3 – December 7, 2009. Visit www.siemens-foundation.org on December 7, 2009 at 9:30 am EST to view a live webcast of the National Finalist Award Presentation. You can also log into and follow the Siemens Foundation on Twitter (http://twitter.com/SFoundation) for the latest information and announcements throughout this year’s competition.

About the Siemens Foundation

The Siemens Foundation provides more than $7 million annually in support of educational initiatives in the areas of science, technology, engineering and math in the United States. Its signature programs, the Siemens Competition in Math, Science & Technology and Siemens Awards for Advanced Placement, reward exceptional achievement in science, math and technology. The newest program, The Siemens We Can Change the World Challenge, encourages K-12 students to develop innovative green solutions for environmental issues. By supporting outstanding students today, and recognizing the teachers and schools that inspire their excellence, the Foundation helps nurture tomorrow’s scientists and engineers. The Foundation’s mission is based on the culture of innovation, research and educational support that is the hallmark of Siemens’ U.S. companies and its parent company, Siemens AG.

For further information, visit www.siemens-foundation.org.

The College Board

The College Board is a not-for-profit membership association whose mission is to connect students to college success and opportunity. Founded in 1900, the College Board is composed of more than 5,700 schools, colleges, universities and other educational organizations. Each year, the College Board serves seven million students and their parents, 23,000 high schools, and 3,800 colleges through major programs and services in college readiness, college admission, guidance, assessment, financial aid, enrollment, and teaching and learning. Among its best-known programs are the SAT®, the PSAT/NMSQT® and the Advanced Placement Program® (AP®). The College Board is committed to the principles of excellence and equity, and that commitment is embodied in all of its programs, services, activities and concerns.

For further information, visit www.collegeboard.com.