Civil Engineering
Graduate programs are offered in coastal and water resources engineering, computing and systems, construction engineering and management, environmental engineering, geotechnical and geoenvironmental engineering, mechanics and materials, structural engineering and mechanics, transportation engineering and materials.
Degrees earned will be distributed as: "Master of Civil Engineering", "Master of Science," and "Doctor of Civil Engineering" without specialization specifications.
Master's Degree Requirements
Four Master's degrees, requiring a minimum of 30 or 31 credit hours, are available. At least two-thirds of a Master's program should be in a well-defined major area of concentration. The MCE is a non-thesis (Option B) degree with other requirements, such as independent projects or core courses, specified in some areas of specialization. A formal minor is not permitted. The MCE is available both on-campus and through distance education. The MSCE degree requires a thesis and a formal minor is optional. Requirements for the MENE and MSENE are the similar to those for the CE degrees.
Doctoral Degree Requirements
The Ph.D. typically requires one year of full-time course work beyond the master's degree and research culminating in a dissertation. The program must develop a well-defined major area of concentration and may include supporting courses outside the major or a formal minor in a related field. All specialty areas, including Environmental Engineering, are included in the one Ph.D. program.
Student Financial Support
Departmental teaching and research assistantships are available including coverage of tuition and health insurance. Fellowships -- full or supplemental to an assistantship -- are available for exceptional applicants. All financial aid recipients are selected on merit-based competition with other applicants. Applications requesting financial aid (both U.S. and international) should be submitted early: December 15 for Fall admission and by July 15 for Spring admission.
More Information
Admission Requirements
Normal minimum GPA requirements include 3.0 overall and in the major. Students who do not meet these academic requirements may take graduate courses through the Non Degree Studies program to demonstrate academic ability, but consultation with the Director of Graduate Programs is strongly advised. Applicants without academic experience in civil engineering, construction engineering, or environmental engineering may be required to take undergraduate courses to remove deficiencies, but graduate credit is not given for these courses. The Graduate Record Examination is NOT required for any applicant (domestic or international) applying to the PhD, MSCE, or MSENE degree programs.
Applicant Information
Civil Engineering (MS and PhD)
- Delivery Method: On-Campus
- Entrance Exam: None
- Interview Required: None
Civil Engineering (MR)
- Delivery Method: On Campus, Online, Hybrid
- Entrance Exam: None
- Interview Required: None
Application Deadlines
- Fall: June 1 (US), March 1 (Int)
- Spring: November 1 (US), July 15 (Int)
- Summer 1: March 15 (US), December 15 (Int)
- Summer 2: May 1 (US), December 15 (Int)
Faculty
Full Professors
- Sankarasubramanian Arumugam
- Morton A. Barlaz
- Joseph F. DeCarolis
Area of Research: Environmental and Energy Policy - John W. Baugh Jr.
- Emily Zechman Berglund
- Francis Lajara De Los Reyes III
- Joel Ducoste
- Henry C. Frey
- Mohammed Awad Gabr
- Jessica Ann Kaminsky
- Murthy N.Guddati
- Abhinav Gupta
- Tasnim Hassan
- Edward J. Jaselskis
- Youngsoo R. Kim
- Detlef R. Knappe
- Mervyn J. Kowalsky
- George F. List
- Min Liu
- Gnanamanikam Mahinthakumar
- James M. Nau
- Margery F. Overton
- Ranji Ranjithan
- William John Rasdorf
- Rudolf Seracino
- Akhtarhusein A. Tayebali
- Billy Merle Williams Jr.
Associate Professors
- Ange Therese Akono
- Alex Albert
Area of Research: Construction Engineering and Management - Douglas F. Call
Area of Research: Environmental & Water Resources - Cassandra Alison Castorena
- Danjue Chen
- Joel Casey Dietrich
- Andrew P. Grieshop
- Jeremiah Johnson
- Brina Mortensen Montoya
- Daniel R. Obenour
Area of Research: Water Resources & Coastal Engineering - Mohammad Pour-Ghaz
- Benjamin Shane Underwood
Assistant Professors
- Katherine Anarde
Area of Research: Environmental, Water Resources, & Coastal Engineering - Tarek Aziz
- Eleni Bardaka
- Jorge Emilio San Juan Blanco
- Nadine Kotlarz
- Ashly Margot Cabas Mijares
- Fernando Garcia Menendez
- Ali Hajbabaie
- Kook Han
- Angela Rose Harris
- Jordan Kern
- Jason Fredrick Patrick
- Giorgio Talotti Proestos
- Jacelyn Jaunice Rice-Boayue
- Andrew Joseph Ziccarelli
Practice/Research/Teaching Professors
- Saran Srikanth Bodda
- Florentino Banaag De La Cruz
- Billy L. Edge
- Meagan Kittle Autry
- James William Levis
- Gregory W. Lucier
- Mohamad Shoaib Samandar
- Elizabeth J. Sciaudone
Adjunct Faculty
- Amin Kamal Akhnoukh
- Michael Scott Breen, Adjunct Professor
Area of Research: Environmental Engineering & Air Quality - Daniel J. Findley, Adjunct Assistant Professor
Area of Research: Transportation Research (ITRE) - Alejandra C. Geiger-Ortiz, Adjunct Assistant Professor
Area of Research: Coastal Engineering - Leta Huntsinger
- Anderson Rodrigo de Queiroz, Adjunct Research Assistant Professor
- Aditya Sinha
Assistant Research Professor
- Tongchuan Wei
Emeritus Faculty
- William L. Bingham
- Robert C. Borden
- Roy H. Borden
- Earl Downey Brill Jr
- Allen C. Chao
- John S. Fisher
- Ajaya K. Gupta
- Kerry S. Havner
- Clinton L. Heimbach
- Yasuyuki Horie
- David West Johnston
- Narendra P. Khosla
- Michael Lloyd Leming
- Vernon C. Matzen
- Stephens W. Nunnally
- M. Shamimur Rahman
- Sami Rizkalla
- Nagui M. Rouphail, Distinguished Professor Emeritus
Area of Research: Transportation Engineering & Systems - J. C. Smith
- John R. Stone
- Harvey E. Wahls
- Paul Z. Zia
Courses
Multi-modal transportation systems; railroads, airports, highways, and other modes. Planning, analysis, and design. Fundamental concepts; supply, demand, flows, impacts, and network optimization.
Prerequisite: C- or better in CE 305
Typically offered in Fall only
Highway capacity; traffic control systems; intelligent vehicle/highway systems; and other advanced topics. Credit for both CE 402 and CE 502 is not allowed.
Prerequisite: C- or better in CE 305
Typically offered in Fall only
Corridor selection; highway alignment; design of roadsides, intersections, and interchanges. Completion of research paper for students taking course for graduate credit. Credit will not be given for both CE 403 and CE 503.
Prerequisite: C- or better in CE 305
Typically offered in Spring and Summer
This course is offered alternate odd years
Analysis, planning and design of air transportation facilities.
Prerequisite: C- or better in CE 305
Typically offered in Fall only
This course is offered alternate even years
Students will learn about railroad technology and how to plan, design, and operate rail systems especially the design of alignments, track, and terminals; and the operation of freight and passenger services (ranging from transit through commuter rail to intercity and high speed rail). Field trips are involved during non-scheduled class time. Students must be able, if necessary, to provide their own transportation.
Prerequisite: CE 305
Typically offered in Spring only
Students will learn about the use of sensors, instrumentation, and big data analysis in transportation systems to observe, monitor, and evaluate performance. This includes the technology employed, the deployment strategies, the challenges associated with obtaining high-quality data, the fusion of data from independent sources, the imputation of missing data elements, and evaluation of performance based on the data assembled. The highway mode is the principal focus, including analyses of travel times, delays, queue dynamics, and spatial and temporal demand patterns.
Typically offered in Spring only
Methods to reduce collisions and injuries on highways. Identifying promising locations, choosing appropriate countermeasures, and evaluating past projects. Understanding the institutional context and establishing appropriate highway design standards.
Typically offered in Spring only
This course is offered alternate even years
Stresses and strains at a point; rosette analysis; torsion and unsymmetrical bending of open and closed sections; nonlinear and curved beams; stress concentration; beams on elastic foundations; shear deformation of beams; classical plasticity; fracture mechanics.
Prerequisite: CE 225 or MAE 314
Typically offered in Fall only
Principles and concepts of design in prestressed concrete including elastic and ultimate strength analyses for flexure, shear, torsion, bond and deflection. Principles of concordancy and linear transformation for indeterminate prestressed structures. Application of pre-stressing to tanks and shells.
Prerequisite: CE 327
Typically offered in Fall only
Theory and behavior of steel structures leading to the development of design requirements contained in current specifications; flexural, torsional and flexural-torsional buckling of columns; plastic analysis of beams and frames; lateral-torsional buckling of beams; stability and strength of flat plates; beam-columns.
Prerequisite: CE 426
Typically offered in Fall only
Theory and design of masonry arches, culverts, dams, foundations and masonry walls subjected to lateral loads.
Prerequisite: CE 327
Typically offered in Spring only
This course is offered alternate years
Analysis of 1D bar and beam, 2D/3D truss, and 2D/3D frame structures using the matrix displacement method. Introduction to the finite element method of analysis by deriving the element stiffness matrices and equivalent nodal loads using the Principle of Virtual Work. Derivation of Timoshenko beam elements for including shear deformation effects. Development of techniques to handle non-standard loading (e.g. support displacements, temperature changes) and accurately model member-releases. Introduction to material/geometric nonlinearity. Implementation of analysis procedures through computer programming and commercial structural analysis software.
Prerequisite: CE 325
Typically offered in Fall only
Development of the finite element method with an emphasis on understanding the fundamental principles governing the analysis technique. Applications to two-dimensional solids with particular attention to applications in structural engineering. Typical modeling considerations are reviewed and applied to the analysis of a realistic structure.
Prerequisite: CE 515
Typically offered in Spring only
Analysis of single and multi-degree-of-freedom structures subjected to various types of excitations and initial conditions. Computational aspects of dynamic analysis. Introduction to approximate methods of analysis.
Prerequisite: CE 425 or CE 525
Typically offered in Spring only
Behavior, strength and design of wood structural members subjected to moment, shear and axial forces. Design of connections and introduction to design of wood structural systems.
Prerequisite: C- or better in CE 325
Typically offered in Spring only
Fundamental behavior of Fiber-Reinforced Polymer (FRP) strengthened/repaired reinforced concrete structures. Creation of sustainable and resilient civil infrastructure by extending the useful life of existing structures using advances materials. Applications to practical strengthening design of realistic reinforced concrete structures.
Typically offered in Fall only
This course consists of three parts. First part covers basic properties of cements, mineral/chemical admixtures, and concrete production. Second part covers mechanical properties including compressive and tensile strength, multi-axial loading, composite models, and fracture mechanics. Models of porosity and microstructures are also discussed. Third part covers durability and deterioration mechanisms including corrosion of steel in concrete, mass transport, service life prediction. Advanced laboratory techniques are discussed. This course also covers emerging topics such as geopolymers and aluminate cements.
Typically offered in Spring only
Introduction to widely-used numerical methods through application to civil and environmental engineering problems. Emphasis will be on implementation and application rather than the mathematical theory behind the numerical methods.
Typically offered in Spring and Summer
Computational approaches to support civil planning, analysis, evaluation and design. Applications to various areas of civil engineering, including construction, structures, transportation and water resources.
Typically offered in Fall only
Computing research and advanced technologies of interest to civil engineers. Issues in the design and development of engineering software systems and engineering modeling of structures, assemblies, processes and phenomena. Additional topics from the most predominant and recent developments and advances in civil engineering computing.
Prerequisite: CE 390
Typically offered in Fall and Spring
Significant soil properties in earthwork engineering, including soil elasticity and soil mineralogy, hydraulic conductivity, stress-strain relations and shear strength, compressibility and compaction. Evaluating laboratory work including plasticity, triaxial compression, permeability, consolidation and compaction tests.
Prerequisite: CE 342
Typically offered in Fall only
Principles and design methodologies for techniques related to densification, including dynamic compaction, vibro-compaction and compaction grouting; drainage, including wick drains, horizontal drains and dewatering; physical and chemical modification, including admixtures, chemical and cement grouting, soil mixing, jet grouting and soil freezing; and use of inclusions, including stone columns, soil nailing, and meta and geosynthetic reinforcement.
Prerequisite: CE 342
Typically offered in Spring only
Communicating effectively is central to the success of any engineering project and to advance in your engineering career. In this course you will learn principles of writing clearly and effectively for the wide range of communication activities professional engineers must do for a variety of audiences. Topics covered include writing reports, writing proposals, delivering presentations, planning and revising writing, providing feedback, and more. Students will get hands-on experience working on a wide range of documents for their career.
P: Graduate Standing
Typically offered in Fall, Spring, and Summer
The course will introduce students to fundamentals of experimental design, measurement systems and applied data analysis techniques and includes 'hands-on' laboratory exercises with sensors and computer-based data acquisition. Emphasis is on general concepts and their practical application towards engineering problems. The goal of the class is to build needed background, skills and vocabulary to develop students' experimental practice rather than focusing on the underlying fundamentals of distinct areas. Students will develop more topic/media-specific knowledge through a team experimental project. Prerequisites include a course in statistics (e.g. ST 370, ST 515 or equivalent) and some coursework or experience involving scientific programming (e.g. CE 536 or 537; Matlab, Python, R, Igor Pro, IDL). Appropriate background can be determined via discussion with instructor.
Typically offered in Fall only
Construction project management and control using network based tools, time-money analysis and other quantitative and qualitative techniques. Planning and scheduling, critical path, lead-lag, resource allocation, uncertainty, cash flow and payment scheduling, change orders, project acceleration, coordination and communication, record keeping. Emphasis on computer-based techniques.
Prerequisite: CE 463
Typically offered in Spring only
This course is offered every third semester
Student teams apply concepts and methods in field studies of real project management processes and construction operations by using principles and methods in Lean Production, Construction, Design, Assembly, Supply, Production Control, and Work Process Design.
Prerequisite: CE 463
Typically offered in Fall only
Legal aspects of contract documents, drawings and specifications; owner-engineer-constructor relationships and responsibilities; bids and contract performance, Labor laws; governmental administrative and regulatory agencies; torts; business organizations; ethics and professionalism.
Typically offered in Spring only
Fundamentals of safety management principles. Detailed review of OSHA regulations and standards critical to construction engineers and managers who expect to design and administer safety related systems in a construction project. Analysis and design of example minimum safety requirements for application in construction field operations. Review of OSHA Standards for the Construction Industry, a review of selected sections of OSHA Standards for General Industry, a review of general principles of construction safety management.
Prerequisite: CE 465 or CE 466
Typically offered in Spring only
This course is offered alternate odd years
Construction is a global business. It is common to find design simultaneously performed in different countries (24/7 design); material procured from sources around the globe; and construction performed by a workforce that is multicultural, multilingual, and multinational. Because of these characteristics those involved with this profession need to embrace this reality and become more aware of the various design and construction practices found throughout the world. This course provides students with such a global awareness by revealing construction practices and innovations found in both developed and emerging countries. To introduce this global awareness, unique construction perspectives will be offered by a consortium of universities located in China, Thailand, Africa, and the U.S. Special topic lecturers will present practices found in other parts of the world including the Middle East, Europe and Central and South America.
Restriction: Graduate standing in the Department of Civil, Construction, and Environmental Engineering unless otherwise agreed upon by instructor
Typically offered in Fall and Spring
Fundamental concepts in financial and risk analysis in construction; accounting and financial metrics in construction; risk assessment and risk management in construction including the cost of risk, decision making strategies, the role of sureties, effects of risk in project delivery methods and contract types; risk effects in project financing including a review of financing sources, considerations for financing local and international projects; and the impact of financial and risk management in strategic planning in construction.
Typically offered in Spring only
This course is offered alternate even years
This course will introduce concepts and applications of Building Information Modeling (BIM) both as a product and as a process. BIM is not only a design tool but is also an approach to building project delivery in which a digital representation of the building process is used to facilitate the exchange and interoperability of information. This course will focus on how BIM is used in construction projects for: 3D modeling; 4D modeling that integrates construction schedule; 5D modeling that integrates schedule and cost; and short-term planning.
R: Major in Civil Engineering or approval from the instructor
Typically offered in Fall only
Mass balances, equation of motion for small particles, small particle interactions, particle collision/fast coagulation, partitioning, adsorption isotherms, fluid mechanics, diffusion, interphase mass transport and resistance models, elementary/non-elementary reactions, residence time distributions.
Prerequisite: CE 282, Graduate standing
Typically offered in Spring only
Concepts in environmental microbiology including cell structure and function, phylogeny, survey of environmentally relevant microbial groups, metabolism under different redox conditions, catabolism of macromolecules, methods in microbial ecology. Relationships to engineering processes and systems will be emphasized.
Prerequisite: Graduate standing in CE, BAE, CHE, or SSC
Typically offered in Fall only
Inorganic and organic environmental chemistry including acid-base equilibria, precipitation, complexation, redox reactions, and natural organic matter. The role of these factors in controlling the fate of contaminants in engineered treatment systems and natural environments.
Prerequisite: Graduate standing in CE, CHE, BAE, NE, MEA, SSC
Typically offered in Fall only
Renewable energy technologies such as wind and solar power make up a growing share of the generation mix. Students develop skills in renewable resource assessment, technical design of renewable energy systems, economic assessment of these technologies, and evaluation of relevant policies. We explore fundamentals and practical aspects of commonly used renewable energy models and extensive energy and resource data sets.
Prerequisite: Senior standing and CE 250 (or equivalent)
Typically offered in Spring only
Introduction to air pollution control fundamentals and design. Fundamentals including physics, chemistry and thermodynamics of pollutant formation, prevention and control. Design including gas treatment and process and feedstock modification. Addressed pollutants including sulfur dioxide, nitrogen oxides, particulate matter, volatile organic compounds, hydrocarbons and air toxins. Investigation of current research. Credit for both CE 476 and CE 576 is not allowed.
Typically offered in Fall only
Solid waste management including generation, storage, transportation, processing, land disposal and regulation. Processing alternatives including incineration and composting. Integration of policy alternatives with evaluation of engineering decisions. Investigation of current research. Credit is only allowed for one of CE 477 and CE 577.
Prerequisite: CE 373
Typically offered in Spring only
Interdisciplinary analysis of energy technology, natural resources, and the impact on anthropogenic climate change. Topics include basic climate science, energetics of natural and human systems, energy in fossil-fueled civilization, the impact of greenhouse gas emissions on climate, and technology and public policy options for addressing the climate challenge. The course is quantitative with a strong emphasis on engineering and science.
Prerequisite: Senior standing
Typically offered in Fall only
Introduction to: risk assessment, health effects, and regulation of air pollutants; air pollution statistics; estimation of emissions; air quality meteorology; dispersion modeling for non-reactive pollutants; chemistry and models for tropospheric ozone formation; aqueous-phase chemistry, including the "acid rain" problem; integrated assessment of air quality problems; and the fundamentals and practical aspects of commonly used air quality models. Credit is allowed only for one of CE/MEA 479 or CE/MEA 579.
Prerequisite: CE 373, CE 382 or CHE 311(CHE Majors), or MEA 421(MEA Majors), Corequisite: ST 370, ST 380(MEA Majors)
Typically offered in Spring only
CE 580 Coastal Modeling prepares students to develop and apply computational models for nearshore ocean waves and circulation, for aid in engineering design.
Prerequisite: Introductory course in fluid mechanics (e.g. CE 282) or permission of instructor
Typically offered in Spring only
This course is offered alternate odd years
Free surface flows of water and air occurring in natural fluid systems and influencing environmental transport and mixing. Review of fundamental principles of fluids, covering the scales relevant to both engineering and geo-physical applications. Topics and examples include waves, instability, stratification, turbulent boundary layers, jets and plumes, and open channel flows. Cannot receive credit for both CE 581 and MEA 581.
Typically offered in Fall only
This course gives an introduction to water wave mechanics for engineers and scientists. Topics include wave generation, propagation, kinematics, transformation, breaking, forces, and dissipation.
Prerequisite: CE 282 or permission of instructor.
Typically offered in Spring only
Coastal environment, engineering aspects of mechanics of sediment movement, littoral drift, beach profiles, beach stability, meteorological effects, tidal inlets, inlet stability, shoaling, deltas, beach nourishment, mixing processes, pollution of coastal waters, interaction between shore processes and man-made structures, case studies.
C- or better in CE 282.
Typically offered in Spring only
Introduction to ground water hydraulics and hydrology. Hydrologic cycle, basic ground water hydraulics, numerical solution of governing equations, ground water hydrology of North Carolina, well design and construction, flow net development, and ground water contamination sources.
Prerequisite: CE 382
Typically offered in Fall only
This course addresses how human inputs affect natural and engineered aquatic systems, through mathematical modeling of system dynamics. Course topics integrate physical, chemical, and biologic processes related to pollutants and lower food-web dynamics. Lectures and assignments cover both theory and application. Applications are relevant to informing management, protection, and restoration of inland and coastal waters.
Prerequisite courses include environmental processes (e.g., CE 373) and quantitative calculus-based hydrology (e.g., CE 383), or permission of instructor.
Typically offered in Spring only
Hydrologic principles underlying procedures for surface water modeling; applications of common hydrologic models to actual watersheds.
Prerequisite: CE 383
Typically offered in Fall only
Extension of the concepts of fluid mechanics and hydraulics to applications in water supply, water transmission, water distribution networks and open channels to include water-supply reservoirs, pump and pipe selection, determinate and indeterminate pipe networks, and analysis of open channels with appurtenances.
Typically offered in Fall only
New or special course on recent developments in some phase of civil engineering. Specific topics and prerequisites identified for each section and varied from term to term.
Typically offered in Fall and Spring
New or special course on recent developments in some phase of civil engineering. Specific topics and prerequisites identified for each section and varied from term to term.
Typically offered in Fall and Spring
New or special course on recent developments in some phase of civil engineering. Specific topics and prerequisites identified for each section and varied from term to term.
Typically offered in Fall and Spring
New or special course on recent developments in some phase of civil engineering. Specific topics and prerequisites identified for each section and varied from term to term.
Typically offered in Fall and Spring
New or special course on recent developments in some phase of civil engineering. Specific topics and prerequisites identified for each section and varied from term to term.
Typically offered in Fall and Spring
New or special course on recent developments in some phase of civil engineering. Specific topics and prerequisites identified for each section and varied from term to term.
Typically offered in Fall and Spring
New or special course on recent developments in some phase of civil engineering. Specific topics and prerequisites identified for each section and varied from term to term.
Typically offered in Fall and Spring
Discussions and reports of subjects in civil engineering and allied fields.
Typically offered in Fall and Spring
Discussions and reports of subjects in civil engineering and allied fields.
Typically offered in Fall and Spring
Discussions and reports of subjects in civil engineering and allied fields.
Typically offered in Fall and Spring
Directed reading of advanced topics in some phase of civil engineering.
Prerequisite: Graduate standing
Typically offered in Summer only
Research- or design-oriented independent study and investigation of a specific civil engineering topic, culminating in final written report.
Typically offered in Fall, Spring, and Summer
Teaching experience under the mentorship of faculty who assist the student in planning for the teaching assignment, observe and provide feedback to the student during the teaching assignment, and evaluate the student upon completion of the assignment.
Prerequisite: Master's student
Typically offered in Fall, Spring, and Summer
For students in non-thesis master's programs who have completed all credit hour requirements for their degree but need to maintain half-time continuous registration to complete incomplete grades, projects, final master's exam, etc.
Prerequisite: Master's student
Typically offered in Summer only
For students in non-thesis master's programs who have completed all credit hour requirements for their degree but need to maintain full-time continuous registration to complete incomplete grades, projects, final master's exam, etc. Students may register for this course a maximum of one semester.
Prerequisite: Master's student
Typically offered in Summer only
Instruction in research and research under the mentorship of a member of the Graduate Faculty.
Prerequisite: Master's student
Typically offered in Summer only
Thesis research.
Prerequisite: Master's student
Typically offered in Fall, Spring, and Summer
For graduate students whose programs of work specify no formal course work during a summer session and who will be devoting full time to thesis research.
Prerequisite: Master's student
Typically offered in Summer only
For students who have completed all credit hour requirements and full-time enrollment for the master's degree and are writing and defending their thesis.
Prerequisite: Master's student
Typically offered in Summer only
Planning and design of urban transportation systems as related to comprehensive urban planning; principles of land use planning, urban thoroughfare planning and regional planning
Prerequisite: CE 501
Typically offered in Spring only
This course is offered alternate odd years
Stream flow, shock wave, queuing, and other macroscopic theories;car following, gap acceptance, and other microscopic theories; distributions of traffic stream parameters; building traffic simulation models.
Typically offered in Fall only
This course is offered alternate odd years
Transportation economics in terms of its supply and demand, costs, pricing, and regulation, especially the way in which the theory of economics in the marketplace and for public and private firms applies to the transportation market given its unique characteristics.
Typically offered in Fall only
Intelligent Transportation Systems (ITS) planning and human factor elements; application of monitoring, communications and information dissemination technologies to transportation systems; advanced traffic management for freeway and arterial systems; traveler information and public transportation systems; automated vehicle and highway systems. ITS evaluation methods and models.
Typically offered in Fall only
This course is offered alternate even years
Advanced signalized traffic control methods at intersections, arterials and networks. Applications of mathematical optimization techniques to signal timing and coordination. Use of traffic simulation and optimization models for signal evaluation and design. Roundabout analysis and design.
Prerequisite: CE 502
Typically offered in Spring only
This course is offered alternate even years
Understanding and debating important current transportation policy issues in the U.S. Raising and allocating funds for building and maintaining the transportation system. Highway, public transit, rail, air, and other modes.
Prerequisite: CE 501 or graduating in Economics or Public Administration
Typically offered in Spring only
This course is offered alternate even years
Theory of stress waves in solids. Origins and nature of longitudinal transverse and surface waves originating at an impact site or from other transient disturbances. Determination of stresses, particle velocities, wave velocities. Wave interaction with other waves and with boundaries and dissimilar materials. Modern instrumentation and seismic refraction exploration.
Typically offered in Fall only
This course is offered alternate years
Stresses and strains (vectors, tensors and indicial notations), general theorems for elastic-plastic solids, constitutive modeling of metals and concrete, numerical implementations of plasticity models.
Prerequisite: CE 515 (old CE 715)
Typically offered in Spring only
This course is offered alternate years
Advanced topics in matrix structural analysis and finite element method. Introductory review of the method, isoparametric quadrilateral element and three-dimensional elements. Energy methods and convergence criteria. Higher order elements. Isoparametric beam and plant elements, shear locking. Isoparametric curved beam and shell elements. Axisymmetric elements, Fourier series load and displacement representation. Analysis of systems with geometric and material nonlinearities.
Prerequisite: CE 526
Typically offered in Spring only
Finite element formulation of equations of motion; advanced analysis techniques for discrete parameter systems; investigation of damping; analysis of continuous systems; applications to civil engineering structures.
Prerequisite: CE 527
Typically offered in Fall only
This course is offered alternate years
Application of probability theory and stochastic processes to study safety of structures. Fundamentals of probability theory and stochastic processes; probabilistic modelings of structural loadings, material properties and risk. Reliability analysisof structures; reliability-based design criteria. Random vibration of simple structures; safety analysis of structures under dynamic loads.
Prerequisite: MA 421
Typically offered in Fall only
This course is offered alternate years
Effects of earthquakes on structures and of design of structures to resist earthquake motions; earthquake mechanisms and ground motions; response of structures to earthquake motions; behavior of materials, structural elements and assemblages subjected to earthquakes; principles of earthquake-resistant design practice; soil-structure interaction; and special topics.
Prerequisite: CE 527
Typically offered in Fall only
Inelastic theory of structural concrete members under flexure, axial load, combined flexure and axial compression, shear and torsion. Yield line theory of slabs. Limit analysis of beams and frames of reinforced and prestressed concrete.
Prerequisite: CE 522
Typically offered in Spring only
This course covers the seismic analysis, assessment and design of concrete building structures. The progression through the course follows four areas, namely: Concrete non-linear material behavior; Frame analysis and design; Wall analysis and design; assessment and retrofit. The emphasis during the course will be on the relationships between engineer's choices, analysis and design.
P: CE 725 or equivalent
Typically offered in Spring only
This course covers the seismic analysis and design of bridge structures. The progression through the course follows six thematic areas, namely: Conceptual design; Analysis approaches; Capacity Design; Response Verification; Assessment and Retrofit of Bridges; and New (or underutilized) frontiers in bridge engineering. The emphasis during the course will be on the relationships between engineer's choices, analysis, and design.
Prerequisite: CE 725
Typically offered in Spring only
This course is in three parts. Part one covers fundamentals of composites including estimating the mechanical and thermomechanical properties, failure of composites, laminate, and shear-lag model. Advanced topics including homogenization theories, Eigenstrain and Eigenstress, dilute, self-consistent and Mori-Tanaka methods are also covered. Part two covers fundamental of fracture mechanics including Griffith theory, stress field at crack tip, energy release rate, crack tip plasticity, and mixed mode fracture. Part three covers interface cracks, cracks approaching an interface, and fracture of composites.
Prerequisite: CE 515 and Corequisite: CE526
Typically offered in Fall only
Design and implementation issues for building real-world computer-aided engineering systems. Engineering data modeling; data definition, query and manipulation methodologies; application program interfaces; problem-oriented languages and software supervisors; and knowledge-based systems to support engineering design and decision making.
Typically offered in Spring only
Concepts of volume change and effective stress, stress-strain behavior of clays and sands, stress path and failure conidtions; mechanistic interaction between solids and water, problems in elasticity and plasticity pertaining to stress distribution, elstic, consolidation and secondary settlements, and tolerance limits to deformation levels.
Deformation and failure of soils. Limit equilibrium analyses for: slope stability, lateral earth pressure, bearing capacity of shallow foundations. Constitutive models for soils. Linear elasticity and theory of plasticity. Critical state model for soil behavior. Limit analysis.
Subsoil investigations; excavations; design of sheeting and bracing systems; control of water; footing, grillage and pile foundations; caisson and cofferdam methods of construction.
Prerequisite: CE 342
Typically offered in Spring only
Dynamics of discrete and continuous systems with application to soil dynamics: dynamic soil properties, analysis of foundation vibration, construction-induced vibration, dynamic soil-structure interaction. Geotechnical earthquake engineering: ground motion characteristics, dynamic response of soil sites, effect of local site conditions on design ground motion, liquefaction of soils.
Introduction to use, manufacturing techniques, design and construction of geosynthetics in geotechnical engineering applications; design and analysis of geotextiles, geonets, geogrids and geomembranes in pavements base and subbase reinforcement, reinforced walls, slopes, moisture barriers, dams and hazardous impoundment, landfill liners and covers.
Prerequisite: CE 548
Typically offered in Spring only
Theoretical analysis and design of highway pavements with critical evaluation of current design practices. Pavement materials characterization; stresses and strains in pavements; traffic consideration; pavement performance models; and actual thickness design of pavements using different methodologies.
Prerequisite: CE 342
Typically offered in Fall only
Fundamental concepts in process of pavement management at both network level and project level. Distress identification and evaluation; concepts and methods for rehabilitation and maintenance techniques; nondestructive testing of pavements; performance prediction models; and principles of prioritization/optimization.
Prerequisite: CE 755
Typically offered in Spring only
This course is offered alternate years
Multiscale characterization of asphalt concrete. Chemical, rheological, and damage characterization of asphalt binder; asphalt binder oxidative aging; asphalt modification; asphalt emulsions; asphalt mastics; fine aggregate matrix; coarse aggregate structure. Graduate course on Asphalt and Bituminous Materials or consent by the instructor.
Typically offered in Spring only
Application of principles of linear and nonlinear viscoelasticity, fracture mechanics and damage mechanics to modeling inelastic behavior of construction materials. Mechanical analog of time-dependent response; linear and nonlinear elastic-viscoelastic correspondence principles; time-temperature superposition; stress intensity factor; energy release rate; J-integral; and continuum damage mechanics.
Prerequisite: CE 515
Typically offered in Spring only
This course is offered alternate years
Computer-based analysis of temporary structures in construction and their design, safety and control. Emphasis on concrete formwork, falsework, earth support, cofferdams, underpinning, lifting and rigging.
Typically offered in Fall only
This course is offered alternate years
Methods of collecting, assembling and analyzing construction productivity data in order to increase construction productivity. Applications of methods improvement techniques such as time-lapse photography, flow charts, process charts and time standards to improvement of construction productivity. Safety and human factors in construction and their relation to construction productivity.
Prerequisite: CE 463
Typically offered in Spring only
Fundamental concepts and methods; construction specific models for integrated materials management; computer usage; vendor analysis and "best-buy;" materials requirement planning and control; management of material waste; automated materials tracking; materials handling; study of current issues; development of practical solution to a real-world problem.
Prerequisite: CE 463, CE 465
Typically offered in Spring only
This course is offered every third semester
Analysis of heavy construction processes as systems in order to optimize the selection and employment of construction equipment. Considerations in system design, cost and productivity estimation, operational procedures, safety and maintenance. Computer applications utilizing analytical and simulation techniques.
Typically offered in Spring only
This course is offered alternate years
Construction engineering of conventional and industrialized building systems. Emphasis in areas of structural systems utilizing cast-in-place concrete, precast concrete, prestressed concrete, structural steel, cold-formed steel, masonry, timber, composite and mixed materials. Mechanisms for resisting and transmitting loads, detailing, fabrication, transportation, erection, stability, shoring, quality control and integration of service systems.
Typically offered in Fall and Spring
Physical-chemical treatment processes for the treatment of water, including sedimentation, flotation, filtration, coagulation, oxidation, disinfection, precipitation, adsorption, and membrane treatment processes. Current issues in drinking water quality and treatment are discussed.
Typically offered in Spring only
Course covers the identification, transport, and fate of hazardious substances in the environment; quantification of human exposures to such substances; dose-response analysis; and uncertainty and variability analysis. The general risk assessment framework, study design aspects for exposure assessment, and quantitative methods for estimating the consequences and probablity of adverse health outcomes are emphasized.
Typically offered in Spring only
This course is offered alternate odd years
Principles of microbiological, biochemical, and biophysical processes used in environmental waste treatment and remediation processes, with particular emphasis on water quality control processes.
Typically offered in Spring only
Movement and fate of pollutant discharges. Development and application of analytical solutions and numerical models. Role of these models in planning and management. Mathematical programming models. Alternative management strategies: direct regulation, charges and transferable discharge permits. Multiple objectives: cost, equity and certainty of outcome.
Typically offered in Fall only
Application of systems analysis methods to design, analysis and management of water resources and environmental engineering.
Typically offered in Spring only
This course is offered alternate years
Stochastic modeling, water resources and environmental data analysis, Dimension reduction, estimation and detection of periodicities in water resources and environmental data, parametric and non-parametric methods in water and environmental modeling.
Typically offered in Spring only
This course is offered alternate odd years
Local, regional and global scale chemical interactions, transport and behavior of trace gases (sulfur carbon, nitrogen, hydrocarbon, and photo-chemical oxidants) in the atmosphere. covers three primary elements of air quality: anthropogenic and natural emissions of trace gases; interactions of the pollutants in the atmosphere; and monitoring and sampling of gaseous and particulate pollutants.
Typically offered in Spring only
Introduction to movement and attenuation of contaminants in the subsurface. Common contaminant sources; advection and dispersion; numerical modeling of contaminant transport; chemical and biological processes in the subsurface; and ground water restoration technology.
Typically offered in Spring only
Hydroclimatology, El-Nino southern oscillation, climate and streamflow forecasting, forecast verification measures, downscaling, Budyko's Framework, long-term water balance, data assimilation, ensemble Kalman Fiter.
Prerequisite: CE 586
Typically offered in Spring only
This course is offered alternate even years
New or special course on advanced developments in some phase of civil engineering. Specific topics and prerequisites identified for each section and varied from term to term.
Typically offered in Fall and Spring
Typically offered in Fall and Spring
Typically offered in Fall and Spring
Typically offered in Fall and Spring
Typically offered in Fall and Spring
Typically offered in Fall and Spring
Typically offered in Fall and Spring
Typically offered in Fall and Spring
Typically offered in Fall and Spring
Typically offered in Fall and Spring
Directed reading of advanced topics in some phase of civil engineering.
Prerequisite: Graduate standing
Typically offered in Fall, Spring, and Summer
Teaching experience under the mentorship of faculty who assist the student in planning for the teaching assignment, observe and provide feedback to the student during the teaching assignment, and evaluate the student upon completion of the assignment.
Prerequisite: Doctoral student
Typically offered in Summer only
For students who are preparing for and taking written and/or oral preliminary exams.
Prerequisite: Doctoral student
Typically offered in Summer only
Instruction in research and research under the mentorship of a member of the Graduate Faculty.
Prerequisite: Doctoral student
Typically offered in Spring and Summer
Dissertation research.
Prerequisite: Doctoral student
Typically offered in Fall, Spring, and Summer
For graduate students whose programs of work specify no formal course work during a summer session and who will be devoting full time to thesis research.
Prerequisite: Doctoral student
Typically offered in Summer only
For students who have completed all credit hour, full-time enrollment, preliminary examination, and residency requirements for the doctoral degree, and are writing and defending their dissertations.
Prerequisite: Doctoral student
Typically offered in Fall and Summer