This course will use green chemistry and engineering principles to assess the catalytic production of fuels and chemicals. Historical context for current processes will be given to contrast available routes for conversions using alternative, more sustainable feedstocks, and processes. These case studies will also serve as platforms for the fundamentals of heterogeneous acid and metal catalysis, including techniques of catalyst synthesis and characterization, as well as an understanding of how reactions occur on surfaces.

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.

An introduction to the properties of solids. Theory of free electrons--classical and quantum. Crystal structure and methods of determination. Electron energy levels in a crystal: weak potential and tight-binding limits. Classification of solids--metals, semiconductors and insulators. Types of bonding and cohesion in crystals. Lattice dynamics, phonon spectra and thermal properties of harmonic crystals.

Power electronics circuits are critical building blocks in a wide range of applications, ranging from mW-scale portable devices, W-scale telecom servers, kW-scale motor drives, to MW-scale solar farms. This course is a design-oriented course and will present fundamental principles of power electronics. Topics include: 1) circuit elements; 2) circuit topology; 3) system modeling and control; 4) design methods and practical techniques. Numerous design examples will be presented in the class, such as solar inverters, data center power supplies, radio-frequency power amplifiers, and wireless power transfer systems.

This course discusses the use of Integrated Assessment Models (IAMs) for climate policy and energy research. The course gives an overview of two types of IAMs: detailed process IAMs that evaluate how mitigation options and technology choices influence regional emissions and global climate; and benefit-cost IAMs that estimate the social cost of carbon or the optimal emission trajectory to maximize global welfare. The course then dives into one detailed process IAM, the Global Change Analysis Model, to demonstrate how IAMs have been applied to examine climate policy choice and impacts, air quality and health co-benefits, etc.

This course discusses the use of Integrated Assessment Models (IAMs) for climate policy and energy research. The course gives an overview of two types of IAMs: detailed process IAMs that evaluate how mitigation options and technology choices influence regional emissions and global climate; and benefit-cost IAMs that estimate the social cost of carbon or the optimal emission trajectory to maximize global welfare. The course then dives into one detailed process IAM, the Global Change Analysis Model, to demonstrate how IAMs have been applied to examine climate policy choice and impacts, air quality and health co-benefits, etc.

This course introduces solid Earth system science, quantifying underlying physical and chemical processes to study the formation and evolution of Earth through time. We discuss how these processes create and sustain habitable conditions on Earth, including feedbacks and tipping points as recorded in the geologic record. Topics include stellar and planetary formation, plate tectonics, seismology, minerals/rocks, the geologic timescale, natural resources, the hydrologic cycle and sedimentation, paleoclimatology, and the "Anthropocene." Students will apply these topics to the recent past to assess human impact on the environment.

Heat and work in physical systems. Concepts of energy conversion and entropy, primarily from a macroscopic viewpoint. Efficiency of different thermodynamic cycles, with applications to everyday life including both renewable and classical energy sources. In the laboratory, students will carry out experiments in the fields of analog electronics and thermodynamics.

The course introduces fundamentals of optics, lasers, and Fourier transforms through lectures and hands-on activities. The topics include ray and wave optics, imaging and image processing, optical Fourier transforms, principles of lasers, and applications in nuclear fusion for renewable energy, environmental sensing, space exploration, ultrafast metrology, chemistry, and physics.

In this course students learn practical applications of optimization methods in energy systems engineering. Students also gain familiarity with techniques via survey of canonical problems in power systems operations and planning. The course teaches practical model development, including formulation and implementation of linear and mixed integer programs in an algebraic programming language. The second half surveys advanced topics, including: managing dimensionality in large-scale problems, technology evaluation, policy evaluation, decision making under uncertainty, and multi-objective optimization.

This course is an introduction to commodities markets (oil, gas, metals, electricity, etc.), and quantitative approaches to capturing uncertainties in their demand and supply. We start from a financial perspective, and traditional models of commodity spot prices and forward curves. Then we cover modern topics: game theoretic models of energy production (OPEC vs. fracking vs. renewables); quantifying the risk of intermittency of solar and wind output on the reliability of the electric grid (mitigating the duck curve); financialization of commodity markets; carbon emissions markets. We also discuss economic and policy implications.