Geological engineering degree overview

Geological engineers carry out technical studies to evaluate the physical landscapes where dams, mines, roads, railways, pipelines, forestry, and other operations that involve extracting natural resources are planned. They provide solutions related to land reclamation, air and water pollution, potential landslides and earthquakes, and environmental sustainability.

Students of geological engineering learn how to apply knowledge of earth materials and earth sciences to human problems and projects. Their areas of study span geology, chemistry, physics and mechanics, calculus, soil mechanics, solid mechanics, mineralogy, rock mechanics, landforms, groundwater hydrology, and engineering law and ethics.

Note: It is important to select a geological engineering training program that is accredited by the Accreditation Board for Engineering and Technology (ABET).

Bachelor’s Degree in Geological Engineering – Four Year Duration
This is the most common credential held in the profession. Bachelor’s degree programs in geological engineering consist of both traditional classroom study and laboratory and field work.

Here is an overview of the typical undergraduate curriculum:

• Introduction to Engineering – engineer roles and responsibilities, engineering disciplines, the engineering design process, scientific principles, prototyping, engineering graphics, engineering technical communication, engineering ethics
• Chemistry for Engineering – chemical bonding, properties of matter, chemical thermodynamics, processes at surfaces
• Differential Calculus – applications of differential calculus to physical sciences and engineering, derivatives of elementary functions, modeling, graphing, optimization
• Introductory Physics for Engineers – heat, thermodynamics, oscillations, waves, and sound
• Mechanics – statics of particles, equilibrium of rigid bodies, rigid body statics and internal forces, trusses; kinematics: rectilinear motion; dynamics: Newton’s Second Law, friction, impulse, momentum, work, and energy
• Technical Communication – oral and written communication in engineering, report writing, business correspondence, oral presentation of technical material
• Soil Mechanics – soil classification, principle of effective stress, analysis of seepage, filter criteria, shear strength, slope stability analysis
• Computational Methods in Geological Engineering – generating computational models; building blocks in modeling, simulation, and parameter estimation
• Solid Mechanics I – deflection of beams, combined axial load and bending moment, inelastic bending, plastic analysis of structures, beam-columns, buckling (stability), principal axes and principal moments of inertia, biaxial stress and strain, Mohr’s Circle
• Introduction to Petrology – optical mineralogy and the classification and genesis of igneous, metamorphic, and sedimentary rocks

Geology
Geology, also known as geoscience and Earth science, is the study of the Earth. Students of the discipline learn about the processes that act upon the Earth, such as floods, landslides, earthquakes, and volcanic eruptions; the materials of which the Earth is made, such as water, oil, metals, and rocks; and the history, evolution, and past climates of the Earth.

Architecture
A degree in architecture will appeal to individuals who have an interest in and appreciation for both the sciences and the arts. This is because architecture is itself the art and science of designing and engineering structures and buildings. It is a field with a foundation in creativity, technology, and social and cultural trends.

Civil Engineering
This degree field is focused on the processes of design and planning of civil infrastructure like roads, tunnels, bridges, dams, railroads, and airports. In their work, civil engineers are concerned with such things as how much weight a structure can support and the environmental issues presented by construction. The emphasis of civil engineering degree programs is math, statistics, engineering systems and mechanics, building codes, and statistical analysis.

Engineering Physics
Students of engineering physics, also referred to as applied physics, learn how to use physics to solve practical problems. For this reason, the field is sometimes referred to as the bridge between physics and engineering. Coursework includes computational physics, materials science, thermodynamics, and nanotechnology.

Environmental Engineering
This branch of engineering is concerned with finding solutions to environmental problems. Degree programs in the field prepare students to work as environmental engineers, who develop plans to prevent and control air and water pollution, improve recycling and waste disposal, and advance public health.

Environmental Science
The basis of this discipline is that all natural things interact. Individuals who earn a degree in environmental science develop plans to prevent, control, or find solutions to environmental issues, such as pollution.

The study of geological engineering develops diverse skills and insights that can be applied in other fields as well:

• Ability to work both independently and as part of a team
• Advanced math and science skills – geological engineers consistently use calculus and trigonometry principles in their analysis and design work
• Observation, logical thinking, problem-solving, and decision making – planning mine operations, mineral processing, and environmental reclamation and restoration are all complex projects
• Field skills / comfortable working outdoors
• GIS (geographic information systems) and GPS (global positioning system) software
• Global perspective
• IT skills / computer modeling
• Physical stamina
• Presenting information both orally and in written form
• Project Management
• Research, data collection, analysis, and record keeping
• Understanding of maps and graphs
• Using statistical applications

Because of the specific nature of geological engineering, most graduates of the discipline work in roles that are directly related to their degree. Here are some of the common occupational categories:

• Academic Research and Teaching
• Civil Engineering and Construction – specifically, in rock stability and soil foundations consultancy roles on tunnel, bridge, and high-rise projects
• Energy / Oil and Gas – safe and sustainable natural resource exploration (oil, gas, uranium, tar sands, geothermal, and coal)
• Forestry – assessing the landscapes where forestry operations are planned
• Governmental and Non-governmental Environmental Protection Agencies and Research Agencies
• Groundwater / Water Resources Management – working with industries and farms that need water sources; consulting on dam construction, well drilling, and dike design