Environmental engineering science (EES) is a multidisciplinary field of engineering science that combines the biological, chemical, geology and physical sciences with engineering to solve environmental issues. Students in this major also need basic engineering classes in fields such as thermodynamics, advanced math, computer modeling and simulation and technical classes in subjects such as statics, mechanics, hydrology, and fluid dynamics. As the student progresses, the upper division electives allow the student to specialize in a range from science and technology, to engineering related classes.
As a recently created program, environmental engineering science has not yet been incorporated into the terminology found among environmentally focused professionals. In the few engineering colleges that offer this major, the curriculum shares more classes in common with environmental engineering than it does with environmental science, that entailing how the engineering aspect focus more on the designing of solutions of the issues rather than discovering what these issues might be. Typically, EES students follow a similar course curriculum with environmental engineers until their fields diverge during the last year of college. The majority of the environmental engineering students must take classes designed to connect their knowledge of the environment to modern building materials and construction methods. This is meant to direct the environmental engineer into a field where they will more than likely assist in building treatment facilities, preparing environmental impact assessments or helping to mitigate air pollution from specific point sources.
Meanwhile, the environmental engineering science student will choose a direction for their career. From the range of electives they have to choose from, these students can move into a fields such as the design of nuclear storage facilities, bacterial bioreactors or environmental policies, as well as so many more fields. These students combine the practical design background of an engineer with the detailed theory found in many of the biological and physical sciences.
Just as in every other job force as well as other given topics âÂÂeverything from business to engineeringâ has various forms of specialization for different tasks, EES is the same in that there are any different concentrations in their work:
Stanford University describes the EES major and related activities below: <blockquote> The Civil and Environmental Engineering department at Stanford University provides the following description for their program in Environmental Engineering and Science: The Environmental Engineering and Science (EES) program focuses on the chemical and biological processes involved in water quality engineering, water and air pollution, remediation and hazardous substance control, human exposure to pollutants, environmental biotechnology, and environmental protection. </blockquote>
The College of Engineering at UC Berkeley defines Environmental Engineering Science, including the following: <blockquote> This is a multidisciplinary field requiring an integration of physical, chemical and biological principles with engineering analysis for environmental protection and restoration. The program incorporates courses from many departments on campus to create a discipline that is rigorously based in science and engineering, while addressing a wide variety of environmental issues. Although an environmental engineering option exists within the civil engineering major, the engineering science curriculum provides a more broadly based foundation in the sciences than is possible in civil engineering </blockquote>
At MIT, the major is described in their curriculum, including the following:
<blockquote> The Bachelor of Science in Environmental Engineering Science emphasizes the fundamental physical, chemical, and biological processes necessary for understanding the interactions between man and the environment. Issues considered include the provision of clean and reliable water supplies, flood forecasting and protection, development of renewable and nonrenewable energy sources, causes and implications of climate change, and the impact of human activities on natural cycles </blockquote>
The College of Engineering at UF defines Environmental Engineering Science as follows: <blockquote>The broad undergraduate environmental engineering curriculum of EES has earned the department a ranking as a leading undergraduate program. The ABET accredited engineering bachelor's degree is comprehensively based on physical, chemical, and biological principles to solve environmental problems affecting air, land, and water resources. An advising scheme including select faculty, led by the undergraduate coordinator, guides each student through the program.
The program educational objectives of the EES program at the University of Florida are to produce engineering practitioners and graduate students who 3-5 years after graduation:
Continue to learn, develop and apply their knowledge and skills to identify, prevent, and solve environmental problems. Have careers that benefit society as a result of their educational experiences in science, engineering analysis and design, as well as in their social and cultural studies. Communicate and work effectively in all work settings including those that are multidisciplinary.</blockquote>
Lower division coursework in this field requires the student to take several laboratory-based classes in calculus-based physics, physics(the most important of sub-categories being mechanics and electromagnetism), chemistry, biology, programming and analysis. This is intended to give the student background information in order to introduce them to the engineering fields and to prepare them for more technical information in their upper division coursework. These courses play a very important role in helping the future people whom decide to study or work in the EES category get a better understanding of physical and chemical properties that underlie the environmental systems around us, especially when attempting to understand the various forms of quality that the worl around us might have.
The upper division classes in Environmental Engineering Science prepares the student for work in the fields of engineering and science with coursework in subjects including the following:
On this track, students are introduced to the fundamental reaction mechanisms in the field of chemical and biochemical engineering. It is largely related to that of EES because these classes teach students to develop methods of synthesizing and purifying desired chemical products and they learn to analyze the chemical makeup of various ingredients, determining how they would interact with each other. This is the bare essence of what EES students do â analyze chemical levels to make sure water and air quality is intact.
For this track, students take classes introducing them to ways to conserve natural resources. This can include classes in water chemistry, sanitation, combustion, air pollution and radioactive waste management. Classes that resource engineers take are largely comparable to those of EES, especially it's Sustainability and Environmental Impact sector, where we try to avoid the depletion of natural resources and create new methods of making renewable energy sources.
To sum it up, geo-engineering is the large scale act of stepping into and aiding the Earth's climate system by attempting to counteract human-caused climate change and other human-caused global impacts. Geo-engineering is related to EES in the sense that it works to mitigate climate change other the world. This examines geo-engineering in further detail.
This is a branch of biology that covers the aspects of organisms in a set environment. It prepares the students for using their engineering and scientific knowledge to solve the interactions between plants, animals and the biosphere. In addition, I has common applications in a variety of fields, some of which include, conversation (biology), wetland management, as well as natural resource management, which are some of the biggest factors that are included within the EES learning environment and work force.
This includes further education about microbial, molecular and cell biology. Classes can include cell biology, virology, microbial and plant biology. This is related to EES on the most basic level, as you must have basic understand of biology works in order to by successful in this major and work force.
This covers in more detail ways the environment can be protected through political means. This is done by introducing students to qualitative and quantitative tools in classes such as economics, sociology, political science and energy and resources.
The multidisciplinary approach in Environmental Engineering Science gives the student expertise in technical fields related to their own personal interest. While some graduates choose to use this major to go to graduate school, students who choose to work often go into the fields of civil and environmental engineering, biotechnology, and research. With an extensive background in sustainability, it is also common to go into the workforce as a Sustainability Manager, or Analysis. And because there is a lesser background in technical math, programming and writing background gives the students opportunities to pursue IT work and technical writing.
"MIT Course Catalog: Department of Civil and Environmental Engineering." Massachusetts Institute of Technology. <http://web.mit.edu/catalogue/degre.engin.civil.shtml>.
2008-2009 Announcement. Brochure. Berkeley, 2008. Engineering Announcement 2008-2009. University of California, Berkeley. <https://web.archive.org/web/20081203005457/http://coe.berkeley.edu/students/EngAnn08.pdf>.