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| title | chunk | source | category | tags | date_saved | instance |
|---|---|---|---|---|---|---|
| Geoprofessions | 2/6 | https://en.wikipedia.org/wiki/Geoprofessions | reference | science, encyclopedia | 2026-05-05T03:47:44.331397+00:00 | kb-cron |
Engineering geologist. (a) Elements of the engineering geologist specialty. The practice of engineering geology involves the interpretation, evaluation, analysis, and application of geological information and data to civil works. Geotechnical soil and rock units are designated, characterized, and classified, using standard engineering soil and rock classification systems. Relationships are interpreted between landform development, current and past geologic processes, ground and surface water, and the strength characteristics of soil and rock. Processes evaluated include both surficial processes (for example, slope, fluvial, and coastal processes), and deep-seated processes (for example, volcanic activity and seismicity). Geotechnical zones or domains are designated based on soil and rocked geological strength characteristics, common landforms, related geologic processes, or other pertinent factors. Proposed developmental modifications are evaluated and, where appropriate, analyzed to predict potential or likely changes in types and rates of surficial geologic processes. Proposed modifications may include such things as vegetation removal, using various types of earth materials in construction, applying loads to shallow or deep foundations, constructing cut or fill slopes and other grading, and modifying ground and surface water flow. The effects of surficial and deep-seated geologic processes are evaluated and analyzed to predict their potential effect on public health, public safety, land use, or proposed development. (b) Typical engineering geologic applications and types of projects. Engineering geology is applied during all project phases, from conception through planning, design, construction, maintenance, and, in some cases, reclamation and closure. Planning-level engineering geologic work is commonly conducted in response to forest practice regulations, critical areas ordinances, and the State Environmental Policy Act. Typical planning-level engineering geologic applications include timber harvest planning, proposed location of residential and commercial developments and other buildings and facilities, and alternative route selection for roads, rail lines, trails, and utilities. Site-specific engineering geologic applications include cuts, fills, and tunnels for roads, trails, railroads, and utility lines; foundations for bridges and other drainage structures, retaining walls and shoring, dams, buildings, water towers, slope, channel and shoreline stabilization facilities, fish ladders and hatcheries, ski lifts and other structures; landings for logging and other work platforms; airport landing strips; rock bolt systems; blasting; and other major earthwork projects such as for aggregate sources and landfills. (Taken from Washington Administrative Code WAC 308-15-053(1)) While engineering geology is applicable principally to planning, design and construction activities, other specialties of geology are applied in a variety of geoprofessional specialty fields, such as mining geology, petroleum geology, and environmental geology. Note that mining geology and mining engineering are different geoprofessional fields.
== Geological engineering ==
Geological engineering is a hybrid discipline that comprises elements of civil engineering, mining engineering, petroleum engineering, and earth sciences. Geological engineers often become licensed as both engineers and geologists. There are thirteen geological-engineering (or geoengineering) programs in the United States that are accredited by the Engineering Accreditation Commission (EAC) of ABET: (1) Colorado School of Mines, (2) Michigan Technological University, (3) Missouri University of Science and Technology, (4) Montana Tech of the University of Montana, (5) South Dakota School of Mines and Technology, (6) University of Alaska-Fairbanks, (7) University of Minnesota Twin Cities, (8) University of Mississippi, (9) University of Nevada, Reno (10) University of North Dakota, (11) University of Texas at Austin, (12) University of Utah, and (13) University of Wisconsin-Madison. Other schools offer programs or classes in geological engineering, including the University of Arizona. Geoengineering or geological engineering, engineering geology, and geotechnical engineering deal with the discovery, development, and production and use of subsurface earth resources, as well as the design and construction of earthworks. Geoengineering is the application of geosciences, where mechanics, mathematics, physics, chemistry, and geology are used to understand and shape our interaction with the earth. Geoengineers work in areas of
mining, including surface and subsurface excavations, and rock burst mitigation energy, including hydraulic fracturing and drilling for exploration and production of water, oil, or gas infrastructure, including underground transportation systems and isolation of nuclear and hazardous wastes; and environment, including groundwater flow, contaminant transport and remediation, and hydraulic structures. Professional geoscience organizations such as the American Rock Mechanics Association or the Geo-Institute and academic degrees such as the bachelor of geoengineering accredited by ABET acknowledge the broad scope of work practiced by geoengineers and stress fundamentals of science and engineering methods for the solution of complex problems. Geoengineers study the mechanics of rock, soil, and fluids to improve the sustainable use of earth's finite resources, where problems appear with competing interests, for example, groundwater and waste isolation, offshore oil drilling and risk of spills, natural gas production and induced seismicity.
== Geophysics ==
Geophysics is the study of the physical properties of the earth using quantitative physical methods to determine what lies beneath the earth's surface. The physical properties of concern include the propagation of elastic waves (seismic), magnetism, gravity, electrical resistivity/conductivity, and electromagnetism. Geophysics has historically been most commonly used in oil exploration and mining, but its popularity in non-destructive investigative work has flourished since the early 1990s. It is also used in groundwater exploration and protection, geo-hazard studies (e.g., faults and landslides), alignment studies (e.g., proposed roadway, underground utilities, and pipelines), foundation studies, contamination characterization and remediation, landfill investigations, unexploded-ordnance investigations, vibration monitoring, dam-safety evaluation, location of underground storage tanks, identification of subsurface voids, and assisting in archeological investigations. (definition from Association of Environmental & Engineering Geologists)
== Geophysical engineering == Geophysical engineering is the application of geophysics to the engineering design of facilities including roads, tunnels, wells and mines.
== Environmental-science and environmental-engineering specialties ==