Lectures and readings focus on bridges, railroads, power plants, steamboats, telegraph, highways, automobiles, aircraft, computers, and the microchip. Historical analysis provides a basis for studying societal impact by focusing on scientific, political, ethical, and aesthetic aspects in the evolution of engineering over the past two and a half centuries. The precepts and the papers will focus historically on engineering ideas including the social and political issues raised by these innovations and how they were shaped by society as well as how they helped shape culture.

Lectures and readings focus on bridges, railroads, power plants, steamboats, telegraph, highways, automobiles, aircraft, computers, and the microchip. We study some of the most important engineering innovations since the Industrial Revolution. The laboratory centers on technical analysis that is the foundation for design of these major innovations. The experiments are modeled after those carried out by the innovators themselves, whose ideas are explored in the light of the social environment within which they worked.

This course teaches fundamental principles of solid mechanics. Equilibrium equations, reactions, internal forces, stress, strain, Mohr's circle, and Hooke's law. Analysis of the stress and deformation in simple structural members for safe and stable engineering design. Axial force in bars, torsion in shafts, bending and shearing in beams, stability of elastic columns, strain transformation, stress transformation, combined loadings.

The course introduces the basic chemical and physical processes of relevance in environmental engineering. Mass and energy balance and transport concepts are introduced and the chemical principles governing reaction kinetics and phase partitioning are presented. We then turn our focus to the applications in environmental engineering problems related to water and air pollution and the global carbon cycle.

Materials in reinforced concrete. Flexural analysis and design of beams. Shear and diagonal tension in beams. Short columns. Frames. Serviceability. Bond, anchorage and development length. Slabs. Special topics. Introduction to design of prestressed concrete.

An introductory course with several demonstration and hands-on components of fabrication with autonomous and robotic systems. Covers formal methods of fabrication and programming of moderately complex elements, including related fabrication platforms, extrusion platforms, various designs of material, structure, and programming of toolpath. The course is centered around lectures with laboratory/virtual studio individual and team-based assignments involving computer-controlled additive manufacturing and robotic systems, student reading, and peer-reviewed presentation and reporting assignments.

Independent Study in the student's area of interest. The work must be conducted under the supervision of a faculty member and must result in a final paper. Permission of advisor and instructor are required. Open to sophomores and juniors. Must fill out Independent Study form.

Goal: introduce undergraduate engineering students to: (a) infrastructure and food system innovations that can advance the triple outcomes of decarbonization, climate resilience and social equity (b) city scale decarbonization pathways and linkage to larger scale national zero carbon pathways (c) fundamentals of inequality and equity (d) hazard risk resilience framework (e) data analysis and systems models for tracking urban zero carbon emissions including material flow analysis sand life-cycle assessment, measuring inequality to inform equity and introductory analysis of resilience pathways.

In an era where civil infrastructure systems are integral to societal functionality and quality of life, CEE420 is to addresses the complexities of these systems, challenged by rapid urbanization and climate change. This course uniquely integrates engineering principles, mathematical concepts, and computer science, empowering you with the skills necessary for designing and maintaining advanced infrastructure systems. Beyond technical expertise, CEE420 emphasizes the development of essential soft skills through innovative educational game development, enabling you to apply theoretical knowledge in practical, real-world scenarios.

This course examines the future of cities. The focus is on the intersection of rapid urbanization with the global grand challenges: climate, water, and energy. We start with an introduction to urbanization, how to characterize the shape and scale of cities, and the role they play at the global scale geophysically and socio-economically. We then examine heat, air and water flow in urban areas, focusing on how they induce urban heat islands, exacerbate floods, modify power consumption, and reduce thermal comfort. We conclude the course with an examination of how buildings and cities can be designed to be more sustainable, resilient and livable.

Fundamentals of probabilistic risk analysis. Stochastic modeling of hazards. Estimation of extremes. Vulnerability modeling of natural and built environment. Evaluation of failure chances and consequences. Reliability analysis. Decision analysis and risk management. Case studies involving natural hazards, including earthquakes, extreme winds, rainfall flooding, storm surges, hurricanes, and climate change, and their induced damage and economic losses.

Topics in the design and analysis of steel structures are covered such as geometric properties and stresses of built-up shapes, columns, beams, and tension members.

An introduction to the science of water quality management and pollution control in natural systems; fundamentals of biological and chemical transformations in natural waters; indentification of sources of pollution; water and wastewater treatment methods; fundamentals of water quality modeling.

Under the direction of a faculty member, each student carries out independent study. Prior to course registration, students must complete a departmental Graduate Independent Study form that describes the work being undertaken, and have the form approved by the supervising faculty member and the Director of Graduate Studies.

Under the direction of a faculty member, each student carries out independent study. Prior to course registration, students must complete a departmental Graduate Independent Study form that describes the work being undertaken, and have the form approved by the supervising faculty member and the Director of Graduate Studies. Usually taken in the Spring semester.

Under the direction of a faculty member, each student carries out research and presents the results. Directed research is normally taken during the first year of study. The total grading of the course is 25% poster presentation and 75% submitted work.

This is a continuation of CEE 509. Each student carries out research, writes a report and presents the research results. Doctoral candidates must complete this course one semester prior to taking the general examination. The total grading of the course is based 10% on oral presentation and written "poster" communication skills and 90% based on advisors evaluation of the semester's work.

This course focuses on: a) interdisciplinary conceptual research frameworks to address multi-scale/-sector/-objective urban systems with zero carbon resilience and equity goals; b) city scale carbon accounting incorporating MFA and LCA; c) multi-scale modeling of nested zero carbon pathways in communities; d) data analysis of inequality to inform equity in designing just infrastructure transitions; e) infrastructure and environment related health risk assessment following the global burden of disease methodology; f) measuring carbon and resilience co-benefits of distributed infrastructure systems exploring nexus linkages.

The course looks at the most inventive structures and technologies, demonstrating their use of form finding techniques in creating complex curved surfaces. The first part introduces the topic of structural surfaces, tracing the ancient relationship between innovative design and construction technology and the evolution of surface structures. The second part familiarizes the student with membranes(systems, form finding techniques,materials and construction techniques.) The third part focuses on rigid surfaces. The fourth part provides a deeper understanding of numerical form finding techniques.

Advanced topics in the design and analysis of steel structures are covered. These topics include local and global stability (buckling), second-order effects of combined bending and axial loads, and torsion.

This class introduces the components of the hydrologic cycle and their interconnections in a rigorous, quantitative manner. The class focuses on exercises using observational data. There is a modeling and data analysis component using Python and Jupyter Notebooks.

The course provides the theoretical bases for a quantitative description of complex interactions between hydrologic cycle, vegetation and soil biogeochemistry. The first part of the course focuses on modeling the water, carbon and energy dynamics within the soil-plant-atmosphere system at timescales ranging from minute to daily; the second part incorporates rainfall unpredictability and provides a probabilistic description of the soilplant system valid at seasonal to interannual timescales. These concepts are important for a proper management of water resources and terrestrial ecosystems.

This course focuses on ground-based and satellite observations of aerosol particles and their impacts on climate through modeling studies. Course material includes satellite and ground-based measurements of aerosol particles, mathematical formulation of transport, and numerical models of aerosol distribution. It studies how aerosols impact climate change through direct and indirect effects including cloud-aerosol interactions.

This course focuses on mathematical modeling of geochemical reactions, including aqueous phase and water-mineral reactions. We examine how the rates of reactions and fluid flow are interrelated and how to write numerical models that couple these processes. We start with reaction path modeling, and then move to reactive transport modeling. Relevant systems include 1D flow in porous media, 2D pore-network flow, and flow in fractures. Applications are drawn from a variety of problems relevant to environmental engineering and geosciences.

The course explores the latest advancements in decarbonizing water treatment and revolutionizing the approach to this critical sector. Focused on addressing challenges posed by climate change, the course provides an overview of cutting-edge techniques and policies to reduce carbon emissions and enhance water treatment processes' sustainability. Students gain practical experience building an interactive database to organize and analyze research findings, and have the opportunity to present their research at a real conference. Industry leader guest lecturers will share valuable insights and real-world examples of decarbonization in action.

Students learn different methods required for data analysis and interpretation of processes related to water and the environment. The emphasis is on formulating questions, choosing appropriate statistical tools for a given problem, and drawing appropriate conclusions from the analyses. The course covers concepts related to statistical inference and common probabilistic models, linear regression, and exposes the students to non-parametric statistics; students also learn how to perform these analyses using the R programming language. Statistical methods are introduced through the use of hands-on analyses with real data.

Humans are increasingly affecting environmental systems throughout the world. To understand the environmental impacts, quantitative modeling tools are needed. This course introduces quantitative modeling approaches for environmental systems, including global models for carbon cycling; local and regional models for water, soil, and vegetation interactions; models for transport of pollutants in both water and air; and models for population dynamics and the spread of infectious disease. Students will develop simple models for all of these systems and apply the models to a set of practical problems.

This course investigates ancient architecture beyond the disciplinary boundaries of Art History and Civil Engineering. Students will master relevant elements of structural engineering to solve problems underlying the realization of large structures, including their design, materials, and construction. Students will also historically contextualize architecture, including the technological developments, sociological aspects, and aesthetic underlying these monuments. Course projects are based on collaborative group work. In fall 2024, this course will focus on the architecture of ancient Greece, including a planned trip to Athens.

Fundamental principles of solid mechanics: equilibrium equations, reactions, internal forces, stress, strain, Hooke's law, torsion, beam bending and deflection, and analysis of stress and deformation in simple structures. Integrates aspects of solid mechanics that have applications to mechanical and aerospace structures (engines and wings), as well as to microelectronic and biomedical devices. Topics include stress concentration, fracture, plasticity, and thermal expansion. The course synthesizes descriptive observations, mathematical theories, and engineering consequences.

Emphasizes the connection between microstructure and properties in solid-state materials. Topics include crystallinity and defects, electronic and mechanical properties of materials, phase diagrams and transformations, and materials characterization techniques. Ties fundamental concepts in materials science to practical use cases with the goal of solving complex challenges in sustainability and healthcare, among others.