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AA 257: Structural Health Monitoring

Structural health monitoring (SHM) is an emerging technology that provides high-resolution real-time state-sensing, awareness, and self-diagnostic capabilities of structures in service enabled by different types of sensors. SHM is a technology that is designed to interface with the industrial internet of things (IIoT) environment (a) to extend the duration of the service life; (b) to increase the reliability; (c) to reduce the maintenance cost and operational cost. The course will provide in-depth knowledge of two basic damage detection methods for SHM, (a) active sensing and (b) passive sensing. This course will also discuss different kinds of smart materials and sensors, including piezoelectric materials as sensing and actuating elements to interrogate the structures. Advanced signal processing techniques and different types of diagnostics techniques will be discussed and applied to various damage scenarios for qualitative and quantitative measurements. The class will involve structural dynamics, wave propagation, signal processing, finite element methods, and study test cases. Prerequisite: 240 or consent of instructor.
Terms: Spr | Units: 3
Instructors: ; Chang, F. (PI)

BIO 117: Biology and Global Change (EARTHSYS 111, EARTHSYS 217, ESS 111)

The biological causes and consequences of anthropogenic and natural changes in the atmosphere, oceans, and terrestrial and freshwater ecosystems. Topics: glacial cycles and marine circulation, greenhouse gases and climate change, tropical deforestation and species extinctions, and human population growth and resource use. Prerequisite: Biology or Human Biology core or BIO 81 or graduate standing.
Terms: Win | Units: 4 | UG Reqs: GER: DB-NatSci, WAY-SMA

BIO 234: Conservation Biology: A Latin American Perspective (BIO 144, HUMBIO 112)

Principles and application of the science of preserving biological diversity. Conceptually, this course is designed to explore the major components relevant to the conservation of biodiversity, as exemplified by the Latin American region. The conceptual frameworks and principles, however, should be generally applicable, and provide insights for all regions of the world. All students will be expected to conduct a literature research exercise leading to a written report, addressing a topic of their choosing, derived from any of the themes discussed in class.
Terms: Spr | Units: 3

CEE 100: Managing Sustainable Building Projects

Managing the life cycle of buildings from the owner, designer, and contractor perspectives emphasizing sustainability goals; methods to define, communicate, coordinate, and manage multidisciplinary project objectives including scope, quality, life cycle cost and value, schedule, safety, energy, and social concerns; roles, responsibilities, and risks for project participants; virtual design and construction methods for product, organization, and process modeling; lifecycle assessment methods; individual writing assignment related to a real world project. Fulfills WIM requirement for CEE majors. Co-taught with ARCH 542/741 Managing Sustainable Design and Decarbonization Projects at Howard University.
Terms: Aut | Units: 4 | UG Reqs: GER:DB-EngrAppSci

CEE 176A: Energy Efficient Buildings

Quantitative evaluation of technologies and techniques for reducing energy demand of residential-scale buildings. Heating and cooling load calculations, financial analysis, passive-solar design techniques, water heating systems, photovoltaic system sizing for net-zero-energy all-electric homes.
Terms: Aut, Sum | Units: 3-4 | UG Reqs: GER:DB-EngrAppSci

CEE 176B: 100% Clean, Renewable Energy and Storage for Everything (CEE 276B)

This course discusses elements of a transition to 100% clean, renewable energy in the electricity, transportation, heating/cooling, and industrial sectors for towns, cities, states, countries, and companies. It examines wind, solar, geothermal, hydroelectric, tidal, and wave characteristics and resources; electricity, heat, cold and hydrogen storage; transmission and distribution; matching power demand with supply on the grid: efficiency; replacing fossil with electric appliances and machines in the buildings and industry; energy, health, and climate costs and savings; land requirements; feedbacks of renewables to the atmosphere; and 100% clean, renewable energy roadmaps to guide transitions.
Terms: Spr | Units: 3-4 | UG Reqs: GER:DB-EngrAppSci, WAY-AQR
Instructors: ; Jacobson, M. (PI)

CEE 207A: Understand Energy (CEE 107A, EARTHSYS 103, ENERGY 107A, ENERGY 207A)

NOTE: This course will be taught in-person on main campus, lectures are recorded and available asynchronously. Energy is the number one contributor to climate change and has significant consequences for our society, political system, economy, and environment. Energy is also a fundamental driver of human development and opportunity. In taking this course, students will not only understand the fundamentals of each energy resource - including significance and potential, conversion processes and technologies, drivers and barriers, policy and regulation, and social, economic, and environmental impacts - students will also be able to put this in the context of the broader energy system. Both depletable and renewable energy resources are covered, including oil, natural gas, coal, nuclear, biomass and biofuel, hydroelectric, wind, solar thermal and photovoltaics (PV), geothermal, and ocean energy, with cross-cutting topics including electricity, storage, climate change and greenhouse gas emissions (GHG), sustainability, green buildings, energy efficiency, transportation, and the developing world. The 4 unit course includes lecture and in-class discussion, readings and videos, homework assignments, one on-campus field trip during lecture time and two off-campus field trips with brief report assignments. Off-campus field trips to wind farms, solar farms, nuclear power plants, natural gas power plants, hydroelectric dams, etc. Enroll for 5 units to also attend the Workshop, an interactive discussion section on cross-cutting topics that meets once per week for 80 minutes (Mondays, 12:30 PM - 1:50 PM). Open to all: pre-majors and majors, with any background! Website: https://understand-energy-course.stanford.edu/ CEE 107S/207S Understand Energy: Essentials is a shorter (3 unit) version of this course, offered summer quarter. Students should not take both for credit. Prerequisites: Algebra.
Terms: Aut, Spr | Units: 3-5

CEE 224A: Sustainable Development Studio

Project-based. Sustainable design, development, use and evolution of buildings; connections of building systems to broader resource systems. Areas include architecture, structure, materials, energy, water, air, landscape, and food. Projects use a cradle-to-cradle approach focusing on technical and biological nutrient cycles and information and knowledge generation and organization. May be repeated for credit.
Terms: Aut, Win | Units: 3 | Repeatable for credit
Instructors: ; Katz, G. (PI); Lepech, M. (PI)

CEE 226E: Techniques and Methods for Decarbonized and Energy Efficient Building Design

This class explores innovative methods for designing, developing, and financing zero carbon and zero energy buildings. At this pivotal moment, as building codes in California and around the world move towards decarbonization and all electric buildings, this class will ideally position students to enter the field of the built environment with the tools to tackle the quickly changing industry. Students will learn best practices to reduce energy and integrate solar PV generation and battery energy storage in commercial buildings in pursuit of Net Zero Energy and Net Zero Carbon buildings. The class is taught by Peter Rumsey, a widely recognized global leader in energy efficiency and sustainable building design. Lectures include presentations and panels featuring foremost experts and practitioners in the field of green buildings. Optional site visits to the Bay Area's most notable decarbonized and green buildings. CEE 176A and CEE 156/256 or similar courses are recommended prerequisites. All students participate in a group-based, term project focused on the design of a Net Zero Carbon building. Topics covered in this course include: understanding the importance of building envelopes in a successful design, designing a heating system without natural gas, calculating building energy use, optimizing daylighting and electrical lighting, reducing plug load power use, quantifying embodied and lifetime operating carbon emissions from buildings, sizing photovoltaic and battery storage systems, and financing energy efficiency, PV, and battery systems.
Terms: Spr | Units: 2-3
Instructors: ; Rumsey, P. (PI)

CEE 255: Introduction to Sensing Networks for CEE (CEE 155)

Introduce the design and implementation of sensor networks for monitoring the built and natural environment. Emphasis on the integration of modern sensor and communication technologies, signal processing and statistical models for network data analysis and interpretation to create practical deployments to enable sustainable systems, in areas such as energy, weather, transportation and buildings. Students will be involved in a practical project that may involve deploying a small sensor system, data models and analysis and signal processing. Limited enrollment.
Terms: Spr | Units: 3-4

CEE 256: Building Systems Design & Analysis (CEE 156)

HVAC, lighting, and envelope systems for commercial and institutional buildings, with a focus on energy efficient design. Knowledge and skills required in the development of low-energy buildings that provide high quality environment for occupants.
Terms: Win | Units: 3-4

CEE 263C: Weather and Storms (CEE 63)

Daily and severe weather and global climate. Topics: structure and composition of the atmosphere, fog and cloud formation, rainfall, local winds, wind energy, global circulation, jet streams, high and low pressure systems, inversions, el Ni¿o, la Ni¿a, atmosphere/ocean interactions, fronts, cyclones, thunderstorms, lightning, tornadoes, hurricanes, pollutant transport, global climate and atmospheric optics.
Terms: Aut | Units: 3

CEE 263D: Air Pollution and Global Warming: History, Science, and Solutions (CEE 64)

Survey of Survey of air pollution and global warming and their renewable energy solutions. Topics: evolution of the Earth's atmosphere, history of discovery of chemicals in the air, bases and particles in urban smog, visibility, indoor air pollution, acid rain, stratospheric and Antarctic ozone loss, the historic climate record, causes and effects of global warming, impacts of energy systems on pollution and climate, renewable energy solutions to air pollution and global warming. UG Reqs: GER: DBNatSci
Terms: Win | Units: 3

CEE 263S: Atmosphere/Energy Seminar

Interdisciplinary seminar with talks by researchers and practitioners in the fields of atmospheric science and renewable energy engineering. Addresses the causes of climate, air pollution, and weather problems and methods of addressing these problems through renewable and efficient energy systems. May be repeated for credit.
Terms: Aut, Win, Spr | Units: 1 | Repeatable for credit (up to 99 units total)

CEE 265D: Water and Sanitation in Developing Countries

Economic, social, political, and technical aspects of sustainable water supply and sanitation service provision in developing countries. Service pricing, alternative institutional structures including privatization, and the role of consumer demand and community participation in the planning process. Environmental and public health considerations, and strategies for serving low-income households.
Terms: Win | Units: 1-3

CEE 269A: Environmental Engineering Seminar

Presentations on current research, practice and thinking in environmental engineering by visiting academics and practitioners.
Terms: Aut | Units: 1 | Repeatable 2 times (up to 2 units total)

CEE 272R: Engineering Future Electricity Systems (ENERGY 272R)

The electricity grid is undergoing a dramatic transformation due to the urgency to decarbonize, improve resilience against climate-induced extreme weather events, and provide affordable reliable access to at-risk communities.This fast-paced course aims to build a systematic understanding of the future electric power grid. Students will learn how to model, simulate, and optimize grid components, with an emphasis on new technologies such as storage, clean energy sources, and electric vehicles. The course is organized in five sections: loads, distribution, transmission, storage, and generation, and within these modules, students will explore the roles of a variety of grid ecosystem participants (e.g. system operators, utilities, aggregators, technology vendors, and consumers). Students will be exposed to grid modeling, optimization, data science, and economics at an introductory level that allows them to perform basic assessments and develop proof of concept ideas in Python. After this course, much of the current literature and technology developments in the electric grid should be readily accessible for those interested in furthering their learning.
Terms: Spr | Units: 3

CEE 272T: SmartGrids and Advanced Power Systems Seminar (EE 292T)

A series of seminar and lectures focused on power engineering. Renowned researchers from universities and national labs will deliver bi-weekly seminars on the state of the art of power system engineering. Seminar topics may include: power system analysis and simulation, control and stability, new market mechanisms, computation challenges and solutions, detection and estimation, and the role of communications in the grid. The instructors will cover relevant background materials in the in-between weeks. The seminars are planned to continue throughout the next academic year, so the course may be repeated for credit.
Terms: Aut, Win, Spr | Units: 1-2 | Repeatable 2 times (up to 4 units total)

CEE 273B: The Business of Water

Freshwater is our most crucial natural resource, but it is facing mounting pressures from climate change and other factors. While public agencies traditionally dominated water management, private water companies are playing an increasingly important (and sometime controversial) role. In many cases, private companies are making critical contributions to meeting societal water needs (e.g., by developing new technologies and finding new ways to reduce water use). In other cases, however, the involvement of private companies has proven controversial (e.g., when private companies have taken over public water supply systems in developing countries such as Bolivia). This course will look at established and emerging businesses in the water sector and the legal, economic, and social issues generated by the private sector's involvement. These businesses include water technology companies (e.g., companies commercializing new desalination or water recycling technologies), venture capitalists, water funds (that directly buy and sell water rights), consulting firms, innovative agricultural companies, and large corporations (that increasingly are adopting corporate stewardship programs). The course will begin with two weeks of introduction to water and the private water sector. After that, each class will focus on a different water company. Company executives will attend each class session and discuss their business with the class. In most classes, we will examine (1) the viability and efficacy of the company's business plan, (2) the legal and/or social issues arising from the business' work, and (3) how the business might contribute to improved water management and policy. Each student will be expected to write (1) two short reflection papers on businesses that visit the class, and (2) a 10- to15-page paper at the conclusion of the class on an idea that the student has for a new water company, on an existing water company of the student's choice, or on a legal or policy initiative that can improve the role that business plays in improving water management (either in a particular sector or more generally). This course is open to graduate students from around the campus. Elements used in grading: Attendance, Class Participation, Written Assignments, Final Paper. Cross-listed with Civil & Environmental Engineering (CEE 273B).
Terms: Win | Units: 1-2

CEE 276G: Sustainability Design Thinking (CEE 176G)

Application design thinking to make sustainability compelling, impactful and realizable. Analysis of contextual, functional and human-centered design thinking techniques to promote sustainable design of products and environments by holistically considering space, form, environment, energy, economics, and health. Includes Studio project work in prototyping, modeling, testing, and realizing sustainable design ideas. Prerequisite: Enrollment limited and by Permission Number only. Email instructor for application form.
Terms: Win, Sum | Units: 3

CEE 278A: Air Pollution Fundamentals

The sources and health effects of gaseous and particulate air pollutants. The influence of meteorology on pollution: temperature profiles, stability classes, inversion layers, turbulence. Atmospheric diffusion equations, downwind dispersion of emissions from point and line sources. Removal of air pollutants via settling, diffusion, coagulation, precipitation, Mechanisms for ozone formation, in the troposphere versus in the stratosphere. Effects of airborne particle size and composition on light scattering/absorption, and on visual range. Prerequisites: MATH 51 or equivalent. Recommended: 101B, CHEM 31A, or equivalents.
Terms: Aut, Win | Units: 3

CEE 301: The Stanford Energy Seminar (ENERGY 301, MS&E 494)

Interdisciplinary exploration of current energy challenges and opportunities, with talks by faculty, visitors, and students. May be repeated for credit.
Terms: Aut, Win, Spr | Units: 1 | Repeatable for credit

EARTHSYS 106: World Food Economy (EARTHSYS 206, ECON 106, ECON 206, ESS 106, ESS 206)

The World Food Economy is a survey course that covers the economic and political dimensions of food production, consumption, and trade. The course focuses on food markets and food policy within a global context. It is comprised of three major sections: structural features (agronomic, technological, and economic) that determine the nature of domestic food systems; the role of domestic food and agricultural policies in international markets; and the integrating forces of international research, trade, and food aid in the world food economy. This 5-unit course entails a substantial group modeling project that is required for all students. Enrollment is by application only. The application is found at https://economics.stanford.edu/undergraduate/forms. Applications will be reviewed on a first-come, first-serve basis, and priority will be given to upper-level undergraduates who need the course for their major, and to graduate students pursuing work directly related to the course. The application submission period will close on March 15
Terms: Spr | Units: 5 | UG Reqs: WAY-SI

ECON 155: Environmental Economics and Policy

Economic sources of environmental problems and alternative policies for dealing with them (technology standards, emissions taxes, and marketable pollution permits). Evaluation of policies addressing local air pollution, global climate change, and the use of renewable resources. Connections between population growth, economic output, environmental quality, sustainable development, and human welfare. Prerequisite for Undergraduates: ECON 50. May be taken concurrently with consent of the instructor.
Terms: Win | Units: 5 | UG Reqs: GER: DB-NatSci, WAY-SI
Instructors: ; Goulder, L. (PI); Yan, J. (GP)

ECON 250: Environmental Economics

We will discuss both theoretical and empirical analyses of environmental problems, ranging from local pollution challenges to global issues such as climate change. Topics include: Analyses of market failures, policy instruments, integrating environmental and distortionary taxes, policy making under uncertainty, valuing the environment, sustainable development, deforestation vs. conservation, and design of climate agreements.
Terms: Aut | Units: 3-5

ECON 341: Public Economics and Environmental Economics Seminar

Issues in measuring and evaluating the economic performance of government tax, expenditure, debt, and regulatory policies; their effects on levels and distribution of income, wealth, and environmental quality; alternative policies and methods of evaluation. Workshop format combines student research, faculty presentations, and guest speakers. Prerequisite: ECON 241 or consent of instructor.
Terms: Aut, Win, Spr | Units: 1-10 | Repeatable for credit

EE 292H: Engineering, Entrepreneurship & Climate Change

The purpose of this seminar series course is to help students and professionals develop the tools to apply the engineering and entrepreneurial mindset to problems that stem from climate change, in order to consider and evaluate possible stabilizing, remedial and adaptive approaches. This course is not a crash course on climate change or policy. Instead we will focus on learning about and discussing the climate problems that seem most tractable to these approaches. Each week Dr. Field and/or a guest speaker will lead a short warm-up discussion/activity and then deliver a talk in his/her area of expertise. We will wrap up with small-group and full-class discussions of related challenges/opportunities and possible engineering-oriented solutions. Class members are asked to do background reading before each class, to submit a question before each lecture, and to do in-class brainstorming. May be repeated for credit.
Terms: Win | Units: 1 | Repeatable for credit
Instructors: ; Field, L. (PI)

EE 293B: Fundamentals of Energy Processes (ENERGY 201B)

For seniors and graduate students. Covers scientific and engineering fundamentals of renewable energy processes involving heat. Thermodynamics, heat engines, solar thermal, geothermal, biomass. Recommended: MATH 19-21; PHYSICS 41, 43, 45
Terms: Win | Units: 3

ENERGY 101: Energy and the Environment (EARTHSYS 101)

Energy use in modern society and the consequences of current and future energy use patterns. Case studies illustrate resource estimation, engineering analysis of energy systems, and options for managing carbon emissions. Focus is on energy definitions, use patterns, resource estimation, pollution.
Terms: Win | Units: 3 | UG Reqs: GER:DB-EngrAppSci, WAY-AQR, WAY-SMA

ENERGY 102: Fundamentals of Renewable Power (EARTHSYS 102)

Do you want a much better understanding of renewable power technologies? Did you know that wind and solar are the fastest growing forms of electricity generation? Are you interested in hearing about the most recent, and future, designs for green power? Do you want to understand what limits power extraction from renewable resources and how current designs could be improved? This course dives deep into these and related issues for wind, solar, biomass, geothermal, tidal and wave power technologies. We welcome all student, from non-majors to MBAs and grad students. If you are potentially interested in an energy or environmental related major, this course is particularly useful.
Terms: Spr | Units: 3 | UG Reqs: GER:DB-EngrAppSci, WAY-SMA

ENERGY 104: Sustainable Energy for 9 Billion (ENERGY 204)

This course explores the global transition to a sustainable global energy system. We will formulate and program simple models for future energy system pathways. We will explore the drivers of global energy demand and carbon emissions, as well as the technologies that can help us meet this demand sustainably. We will consider constraints on the large-scale deployment of technology and difficulties of a transition at large scales and over long time periods. Assignments will focus on building models of key aspects of the energy transition, including global, regional and sectoral energy demand and emissions as well as economics of change. Prerequisites: students should be comfortable with calculus and linear algebra (e.g. Math 20, Math 51) and be familiar with computer programming (e.g. CS106A, CS106B). We will use the Python programming language to build our models.
Terms: Win | Units: 3 | UG Reqs: WAY-AQR

ENERGY 160: Uncertainty Quantification in Data-Centric Simulations (ENERGY 260)

This course provides a brief survey of mathematical methods for uncertainty quantification. It highlights various issues, techniques and practical tools available for modeling uncertainty in quantitative models of complex dynamic systems. Specific topics include basic concepts in probability and statistics, spatial statistics (geostatistics and machine learning), Monte Carlo simulations, global and local sensitivity analyses, surrogate models, and computational alternatives to Monte Carlo simulations (e.g., quasi-MC, moment equations, the method of distributions, polynomial chaos expansions). Prerequisites: algebra (CME 104 or equivalent), introductory statistics course (CME 106 or equivalent).
Terms: Spr | Units: 3

ENVRES 225: E-IPER Current Topics Seminar

For E-IPER Ph.D and Joint M.S. students only. Weekly presentations of E-IPER students' research and other program-related projects. Occasional guest speakers. Individual or team presentation, active participation, and regular attendance required for credit. May be taken for credit a maximum of two times. Enrollment by department consent only. Please contact E-IPER course administrator Mike Diaz (mikediaz@stanford.edu) for permission number to enroll.
Terms: Aut, Win, Spr | Units: 1 | Repeatable 2 times (up to 2 units total)
Instructors: ; Wheaton, M. (PI)

ENVRES 280: Introduction to Environmental and Resource Systems

Required core course restricted to E-IPER Joint M.S. and Dual M.S. students. Introduces students to frameworks and tools to better understand complex social-environmental systems and to intervene in them to address sustainability goals. Students will apply a systems lens and practice course concepts (provided through lectures and readings) by evaluating case studies.
Terms: Spr | Units: 2

ENVRES 290: Capstone Project Seminar in Environment and Resources

Required for and limited to E-IPER Joint M.S. and Dual M.S. students. Propose, conduct and publicly present final individual or team projects demonstrating the integration of professional (M.B.A., J.D., M.D., M.I.P., or Ph.D.) and M.S. in Environment and Resources degrees. Presentation at the Week 10 Capstone Symposium and submission of final product required.
Terms: Aut, Win, Spr | Units: 3

ESS 305: Climate Change: An Earth Systems Perspective

This is an introductory graduate-level course that is intended to provide an overview of leading-edge research topics in the area of climate change. Lectures introduce the physical, biogeochemical, ecological, and human dimensions of climate change, with emphasis on understanding climate change from an Earth System perspective (e.g., nonlinearities, feedbacks, thresholds, tipping points, resilience, vulnerability, risk). The emphasis is on providing an initial introduction to the process by which researchers pose questions and analyze and interpret results.
Terms: Aut | Units: 1-2
Instructors: ; Hoyt, A. (PI)

LAW 2503: Energy Law

The supply of a safe, reliable, low-cost and clean energy for the United States is a key determinant of current and future prosperity. It is also the most important element of both state and federal decarbonization efforts. Electric utilities are also among the most heavily regulated of large firms. This statutory and regulatory framework is composed of a complex patchwork of overlapping state and federal rules that is constantly evolving to meet emerging challenges. In this course, students will acquire a basic understanding of the law of rate-based regulation of utilities. We will then examine the history of natural gas pipeline regulation in the United States, concluding with the introduction of market competition into US natural gas markets and the advent of shale gas. Next, we will cover the basics of the electricity system, including consumer demand, grid operations, power plant technologies and electricity sector economics. We will then revisit cost of service rate regulation as it has been applied in the electricity context. Next, we will examine reform of both rate-regulated and wholesale market-based structures, focusing on various attempts to introduce market competition into specific segments of the industry. Finally, students will examine various approaches to subsidization of utility scale renewable energy and the growth and compensation of distributed energy resources. Throughout, the course will focus on the sometimes cooperative, sometimes competing, but ever evolving federal and state roles in regulating the supply of electric power as a unique example of cooperative federalism. Students will write two 1000-word response papers during the quarter in addition to taking a final exam (composed of two 1000-word essays). Elements used in grading: Class participation (20%), written assignments (40%), and final exam (40%).
Terms: Spr | Units: 3
Instructors: ; Wara, M. (PI)

LAW 2508: The Business of Water

Freshwater is our most crucial natural resource, but it is facing mounting pressures from climate change and other factors. While public agencies traditionally dominated water management, private water companies are playing an increasingly important (and sometime controversial) role. In many cases, private companies are making critical contributions to meeting societal water needs (e.g., by developing new technologies and finding new ways to reduce water use). In other cases, however, the involvement of private companies has proven controversial (e.g., when private companies have taken over public water supply systems in developing countries such as Bolivia). This course will look at established and emerging businesses in the water sector and the legal, economic, and social issues generated by the private sector's involvement. These businesses include water technology companies (e.g., companies commercializing new desalination or water recycling technologies), venture capitalists, water funds (that directly buy and sell water rights), consulting firms, innovative agricultural companies, and large corporations (that increasingly are adopting corporate stewardship programs). The course will begin with two weeks of introduction to water and the private water sector. After that, each class will focus on a different water company. Company executives will attend each class session and discuss their business with the class. In most classes, we will examine (1) the viability and efficacy of the company's business plan, (2) the legal and/or social issues arising from the business' work, and (3) how the business might contribute to improved water management and policy. Each student will be expected to write (1) two short reflection papers on businesses that visit the class, and (2) a 10- to15-page paper at the conclusion of the class on an idea that the student has for a new water company, on an existing water company of the student's choice, or on a legal or policy initiative that can improve the role that business plays in improving water management (either in a particular sector or more generally). This course is open to graduate students from around the campus. Elements used in grading: Attendance, Class Participation, Written Assignments, Final Paper. Cross-listed with Civil & Environmental Engineering (CEE 273B).
Terms: Win | Units: 2

MS&E 243: Energy and Environmental Policy Analysis

Concepts, methods, and applications. Energy/environmental policy issues such as automobile fuel economy regulation, global climate change, research and development policy, and environmental benefit assessment. Group project. Prerequisite: MS&E 241 or ECON 50.
Terms: Spr | Units: 3

PHYSICS 240: Introduction to the Physics of Energy

Energy as a consumable. Forms and interconvertability. World Joule budget. Equivalents in rivers, oil pipelines and nuclear weapons. Quantum mechanics of fire, batteries and fuel cells. Hydrocarbon and hydrogen synthesis. Fundamental limits to mechanical, electrical and magnetic strengths of materials. Flywheels, capacitors and high pressure tanks. Principles of AC and DC power transmission. Impossibility of pure electricity storage. Surge and peaking. Solar constant. Photovoltaic and thermal solar conversion. Physical limits on agriculture.
Terms: Aut | Units: 3
Instructors: ; Laughlin, R. (PI)

STRAMGT 574: Strategic Thinking in Action - In Business and Beyond II (Automotive Industry Disruption)

This six-session Bass seminar is about strategic leadership driving the transformation of the advanced automotive industry. It will build on what students have learned in their MBA core strategic leadership course but will also provide additional conceptual frameworks developed by the instructors to help examine the major seminar topics. The seminar's pedagogy involves informed debate to evaluate and hone well-researched views by the participants. Consequently, there will be an expectation of extensive contributions from all students to the discussion in all of the sessions. Small groups of seminar participants will also be expected to write and present position papers concerning the seminar's analytical topics. The industry scope of the seminar is twofold: First, it is about autonomous, electric, and shared vehicles. And second, it is about the manufacturer and supplier incumbents as well as the tech industry and startup new-entrants. In the course of the seminar discussions, we aim to deepen our understanding of strategic dynamics and transformational change at the societal, industry and organizational levels of our analysis.
Terms: Aut | Units: 2

URBANST 164: Sustainable Cities (EARTHSYS 160)

Community-engaged learning course that exposes students to sustainability concepts and urban planning as a tool for determining sustainable outcomes in the Bay Area. The focus will be on land use and transportation planning to housing and employment patterns, mobility, public health, and social equity. Topics will include government initiatives to counteract urban sprawl and promote smart growth and livability, political realities of organizing and building coalitions around sustainability goals, and increasing opportunities for low-income and communities of color to achieve sustainability outcomes. Students will participate in remote team-based projects in collaboration with Bay Area community partners. Prerequisites: Consent of the instructor. (Cardinal Course certified by the Haas Center.) Apply here: https://docs.google.com/forms/d/e/1FAIpQLSfhY1w5A_PCjmKdMcGNaZ6Hic24T2zvgF7CfcGrL2tWCWnQGg/viewform
Terms: Spr | Units: 4-5 | UG Reqs: WAY-EDP, WAY-SI
Instructors: ; Kos, R. (PI)

URBANST 165: Sustainable Transportation: Policy and Planning in Practice (EARTHSYS 165)

The transportation network is an essential, if often invisible, part of communities. Only when traffic piles up, the subway shuts down, or the sidewalk is closed do we notice the services and infrastructure that are critical to everyday movement. Beyond the everyday effects, transportation planning decisions also have long term consequences for the environment (transportation is the leading source of greenhouse gas emissions in the United States); the economy (transportation is the fourth largest household expenditure after healthcare, housing, and food); and community wellbeing (traffic collisions are the leading cause of death for young people in the United States). This course will interrogate the role of transportation in fostering sustainable communities paying particular attention to how policy and planning decisions contribute to or hinder equitable access, economic vibrancy, environmental protection. Through a combination of lectures, field work, guest speakers, and real-world client projects, this course will provide an introduction to the field of transportation policy and planning. Student will learn about and get hands-on practice with topics such as bicycle and pedestrian design, safety analysis, traffic operations and modeling software, transit planning, and emerging trends such as autonomous vehicles, micromobility, and congestion pricing. (Cardinal Course certified by the Haas Center).
Terms: Win | Units: 4 | UG Reqs: GER:DB-SocSci, WAY-SI
Instructors: ; McAdam, T. (PI)
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