The Environmental and Engineering Geophysical Society (EEGS) is an applied scientific organization founded in 1992.
EEGS is incorporated in the State of Colorado as a not-for-profit corporation and has approximately 650 members. The society's primary activity is its annual meeting. In addition, it develops and distributes a peer-reviewed scientific journal, as well as a newsletter, quarterly. It also publishes, markets, and distributes books and CD-ROMs on the application and use of geophysical technologies.
The annual meeting of the organization, known as the Symposium on the Application of Geophysics to Engineering and Environmental Problems (SAGEEP), is held in the late winter or early spring. Attendance over the last several years averages about 350. SAGEEP is internationally recognized as the leading conference on the practical application of shallow geophysics. It occurs over a 5-day period, with approximately 150 oral and poster presentations, several educational workshops, numerous vendor presentations, and a commercial exhibition. A set of proceedings, comprised of technical papers presented at the conference is distributed. SAGEEP pre-dates EEGS, and proceedings exist for every year starting with 1988.
A peer-reviewed journal, Journal of Environmental and Engineering Geophysics (JEEG), is published quarterly and distributed via mail to the EEGS membership and academic libraries. Articles from recent issues (2005 forward) are available online to members of subscribing institutions through GeoScienceWorld (www.geoscienceworld.org). An electronic newsmagazine, FastTIMES, is also produced quarterly and is distributed via email and as a downloadable file through the society's web page.
There are several student chapters in North America and Canada. In addition, EEGS maintains close ties with the near surface geophysics section (formerly EEGS-European Section) of the European Association of Geoscientists and Engineers, the Near-Surface Geophysics Section of the Society of Exploration Geophysicists, the Near-Surface Focus Group of the American Geophysical Union, and formal affiliated society agreements with several international professional societies.
EEGS Is The Premier Society Championing The Development And Appropriate Use Of Environmental And Engineering Geophysics.
Welcome to the 'What is Geophysics' section of the EEGS web site. The purpose of this page is to provide you with a brief introduction to the field of Environmental and Engineering Geophysics, with links to more detailed information contained within various 'information repositories'.
This web page provides a Near Surface Geophysics Glossary (MS Word document), some fundamental definitions, and descriptions of many of the ways in which geophysics is used - ways in which specific methods or techniques are employed to address environmental and engineering problems. It is also a resource for finding answers to the questions listed below.
We hope that the 'What is Geophysics' section is will be one of the most dynamically evolving parts of www.eegs.org. We suggest you book-mark this page and check back periodically to see the new information that has been added.
What are the commonly used Near Surface Geophysics terms and their definitions?
Click here to open a MS Word file to view a Near Surface Geophysics Glossary. If you have corrections, additions, or suggestions regarding the glossary, please contact Paul Wolfe at Wright State University.
What is Geophysics ? A Question with Many Answers ...
One of the most comprehensive and widely used definitions of geophysics is that provided by Sheriff in the Encyclopedia of Exploration Geophysics. To review this 'classical' definition of geophysics, visit www.seg.org and select the 'What is Geophysics' topic from the 'You and Geophysics' main topic on the menubar.
For the purposes of this site, we refer more specifically to the following definitions - these focus on Environmental and Engineering Geophysics:
Both of these definitions have a common component, namely that geophysics represents a class of subsurface investigations that are non-invasive (i.e. that do not require excavation or direct access to the sub-surface). The exceptions are borehole geophysical methods that expand the use of holes already drilled to access the subsurface on a very localized basis.
In addition, Definition 1. focuses on the key targets of interest (i.e. geology, geological structure, etc.) - a key consideration in understanding the realm of Environmental and Engineering Geophysics.
Definition 2. underscores the near surface aspect (i.e. in contrast to other geophysical applications, such as petroleum or mineral exploration, this type of problem solving deals with shallow depths that are most significant in terms of the lives, work and activities of the earth's human population.)
What are the Types of Problems Addressed?
Generally, environmental and engineering problems fall into the following classes or types:
As described above, information on each of these areas will be developed and added to www.eegs.org dynamically - so please check back periodically to see what new information is available.
How Do Environmental and Engineering Geophysics Relate to Each Other?
In looking at the previous topic, it may not be immediately apparent that there are distinct components of environmental and engineering sub-disciplines within each 'problem' or application area.
Applications, such as Groundwater and especially contaminant plume mapping, UXO, and Archeology are closely aligned with Environmental Geophysics. Here, the focus is on human health, society and history in contrast to the engineering properties and structures on which Engineering Geophysics focuses.
Other applications that focus primarily on the Environmental sub-discipline include pre-development base line studies and re-development studies (i.e. Brownfields)
Infrastructure applications have more of an Engineering' component, that is, dealing with the detection and characterization of dangerous roadbed conditions underlying highways, for example. This type of application may involve detecting voids under roadways due to underground (i.e. mining or tunneling) excavations, or characterizing the relative integrity of reinforcing structures in bridges or other transportation structures.
Other applications that focus primarily on the Engineering sub-discipline of Environmental and Engineering Geophysics include Dam Safety, and Civil Engineering (including determining the engineering properties of rocks and soils before construction is planned).
However, it is not always possible to draw such clear distinctions between each sub-discipline. For instance, there are clearly components of both Environmental and Engineering Geophysics at work in Geohazards studies.
What are the Benefits of Geophysics?
Environmental and Engineering Geophysics offers a unique window into the earth as a means of detecting sub-surface conditions, and its relevancy lies in the concrete and cost-effective benefits it delivers. These include:
What Geophysical Methods are Available?
As noted previously, geophysical methods as applied to Environmental and Engineering Geophysics were derived from other principal areas of subsurface investigation, including petroleum, mineral and groundwater exploration.
With this in mind, the methods or techniques most commonly employed by practitioners include:
For a brief introduction to each of these methods, please refer to the following links that have been provided courtesy of several professional consulting groups. (The use of these links does not represent an endorsement of products or services by EEGS or its Board or Directors.)
Note that information about geophysical methods will be added in future to this site and you may want to check back periodically for the latest information.
How are Geophysical Methods Applied in Practice?
The implementation of geophysical methods is a structured process that consists of a number of key steps, including:
After these basic questions have been answered and the project approved, the geophysical work will commence.
Typically, Environmental and Engineering Geophysics consists of field surveys conducted along oriented lines (i.e. survey grids) over the desired area of interest. For more information on field surveying, you may want to refer to the links provided above in the 'What Geophysical Field Methods are Available' section.
How are Data and Information Analyzed and Interpreted?
As the field of Environmental and Engineering Geophysics has matured in the last fifteen years, the nature of its application is also changing. Formerly, geophysicists were often called in to address issues that had already reached a 'crisis' state. For example, a community may have discovered the presence of tainted water in their wells. Professionals were called in to map and assess the associated contaminant plumes as a means of determining the extent of the problem and develop possible remediation actions.
Now, however, the application of environmental and engineering geophysical surveys is increasingly becoming a 'planned' activity that is included in budgeting (for example, in highway construction projects or dam construction).
A prerequisite for both of these types of implementations (i.e. crisis-response and planned) is the availability of data that are reliably and accurately interpreted and presented. Typically, data evolve through a 'life-cycle' that consists of the following stages:
Ultimately, the objective is to develop an integrated presentation of all available data and information that can be used not only for decision-making but for other things as well, such as establishing time-indexed baseline information. Another increasingly important objective is to ensure that the data and information are archived for future access (i.e. results may be required for reference in future activities such as re-measurements to compare evolution of conditions over time, or for legislative or judicial procedures).
What are the Costs of Geophysics?
Cost is, of course, a key consideration. Most Environmental and Engineering Geophysical surveys have a cost structure that is similar to that of any licensed professional: an hourly consulting fee plus equipment rental costs. In addition, there are associated costs of mobilization (since most geophysical surveys require acquisition of data in the field), instrumentation amortization, data processing and interpretation, and report writing and presentation.
Ultimately, the application of geophysics must be assessed in terms of its projected costs and benefits as indicated above. EEGS professionals are trained to advise in developing cost and benefit assessments. It makes no sense to conduct a geophysical survey if the costs are projected to exceed any possible economic gains, or to exceed the project's operational budget. In general, however, geophysical surveys are almost always substantially less expensive than traditional non-technical means of investigation such as excavation or drilling.
Who Can Provide the Data Acquisition, Software and Services Required?
Many of the people who are available to assist in addressing Environmental and Engineering problems are members of EEGS. To find out more about who is available to address your specific issues or provide you with more information, you may want to browse our supplier links or our Board of Directors list.
When working with an EEGS member, you may want to keep in mind that our role is to:
But, first-and-foremost, our role is to service the groups who require our assistance. This commitment is expressed in our Code of Ethics that states that Environmental and Engineering Geophysicists have a responsibility to:
As you browse this web site, we hope that you will gain more familiarity with the concepts, practices and benefits of Environmental and Engineering Geophysics as well as greater contact with the professional members of our community. We are ready to work with you to address the specific issues that are most important to your community, work and well being.