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21 - 30 of 43 results for: EARTHSYS

EARTHSYS 178M: Introduction to Environmental Ethics (ETHICSOC 178M, ETHICSOC 278M, PHIL 178M, PHIL 278M, POLISCI 134L)

How should human beings interact with the natural world? Do we have moral obligations toward non-human animals and other parts of nature? And what do we owe to other human beings, including future generations, with respect to the environment? In this course, we will tackle ethical questions that confront us in our dealings with the natural world, looking at subjects such as: animal rights; conservation; economic approaches to the environment; access to and control over natural resources; environmental justice and pollution; climate change; technology and the environment; and environmental activism. We will frame our inquiry with leading ethical theories and divide our approach to these topics by ecosystem, dedicating time to each unique environment and its specific nuances: aquatic, desert/tundra, forest/grassland, and the increasingly recognized environment of Space.
Terms: Win | Units: 4-5 | UG Reqs: GER:EC-EthicReas, WAY-ER

EARTHSYS 183: Adaptation (ESS 185)

Adaptation is the process by which organisms or societies become better suited to their environments. In this class, we will explore three distinct but related notions of adaptation. Biological adaptations arise through natural selection, while cultural adaptations arise from a variety of processes, some of which closely resemble natural selection. A newer notion of adaptation has emerged in the context of climate change where adaptation takes on a highly instrumental, and often planned, quality as a response to the negative impacts of environmental change. We will discuss each of these ideas, using their commonalities and subtle differences to develop a broader understanding of the dynamic interplay between people and their environments. Topics covered will include, among others: evolution, natural selection, levels of selection, formal models of cultural evolution, replicator dynamics, resilience, rationality and its limits, complexity, adaptive management.
Terms: Win | Units: 3 | UG Reqs: WAY-SMA

EARTHSYS 185: Feeding Nine Billion

Feeding a growing and wealthier population is a huge task, and one with implications for many aspects of society and the environment. There are many tough choices to be made- on fertilizers, groundwater pumping, pesticide use, organics, genetic modification, etc. Unfortunately, many people form strong opinions about these issues before understanding some of the basics of how food is grown, such as how most farmers currently manage their fields, and their reasons for doing so. The goal of this class is to present an overview of global agriculture, and the tradeoffs involved with different practices. Students will develop two key knowledge bases: basic principles of crop ecology and agronomy, and familiarity with the scale of the global food system. The last few weeks of the course will be devoted to building on this knowledge base to evaluate different future directions for agriculture.
Terms: Win | Units: 4 | UG Reqs: WAY-AQR

EARTHSYS 197: Directed Individual Study in Earth Systems

Under supervision of an Earth Systems faculty member on a subject of mutual interest.
Terms: Aut, Win, Spr | Units: 1-9 | Repeatable for credit

EARTHSYS 199: Honors Program in Earth Systems

Honors Program in Earth Systems
Terms: Aut, Win, Spr, Sum | Units: 1-9 | Repeatable for credit
Instructors: Ardoin, N. (PI) ; Arrigo, K. (PI) ; Asner, G. (PI) ; Benjamin-Chung, J. (PI) ; Block, B. (PI) ; Boggs, C. (PI) ; Boucher, A. (PI) ; Cain, B. (PI) ; Caldwell, M. (PI) ; Casciotti, K. (PI) ; Chamberlain, P. (PI) ; Crowder, L. (PI) ; Daily, G. (PI) ; Davis, J. (PI) ; Denny, M. (PI) ; Diffenbaugh, N. (PI) ; Dirzo, R. (PI) ; Dunbar, R. (PI) ; Durham, W. (PI) ; Egger, A. (PI) ; Ernst, W. (PI) ; Fendorf, S. (PI) ; Field, C. (PI) ; Francis, C. (PI) ; Frank, Z. (PI) ; Freyberg, D. (PI) ; Fringer, O. (PI) ; Fukami, T. (PI) ; Gerritsen, M. (PI) ; Gilly, W. (PI) ; Gordon, D. (PI) ; Gorelick, S. (PI) ; Goulder, L. (PI) ; Hadly, E. (PI) ; Hayden, T. (PI) ; Hecker, S. (PI) ; Hilley, G. (PI) ; Ingle, J. (PI) ; Jones, J. (PI) ; Kennedy, D. (PI) ; Kennedy, J. (PI) ; Knight, R. (PI) ; Koseff, J. (PI) ; Kovscek, A. (PI) ; Lambin, E. (PI) ; Litvak, L. (PI) ; Lobell, D. (PI) ; Long, S. (PI) ; Luby, S. (PI) ; Masters, G. (PI) ; Matson, P. (PI) ; Micheli, F. (PI) ; Monismith, S. (PI) ; Mooney, H. (PI) ; Mordecai, E. (PI) ; Naylor, R. (PI) ; Orr, F. (PI) ; Ortolano, L. (PI) ; Palumbi, S. (PI) ; Payne, J. (PI) ; Peay, K. (PI) ; Pringle, J. (PI) ; Schoolnik, G. (PI) ; Seto, K. (PI) ; Somero, G. (PI) ; Sperling, E. (PI) ; Sweeney, J. (PI) ; Switzer, P. (PI) ; Tabazadeh, A. (PI) ; Thomas, L. (PI) ; Thompson, B. (PI) ; Victor, D. (PI) ; Vitousek, P. (PI) ; Walbot, V. (PI) ; Watanabe, J. (PI) ; Welander, P. (PI) ; Weyant, J. (PI) ; Wiederkehr, S. (PI) ; Wong-Parodi, G. (PI) ; Woodward, J. (PI) ; Zoback, M. (PI)

EARTHSYS 210B: Senior Capstone and Reflection

Terms: Win | Units: 3
Instructors: Nevle, R. (PI)

EARTHSYS 210P: Earth Systems Capstone Project

Students work independently or in groups to complete their Senior Capstone Projects. They will participate in regular advising meetings with the instructor(s), and will give a final presentation on their projects at the end of the quarter in a special Earth Systems symposium. Prerequisite: EARTHSYS 210A or 210B. https://earth.stanford.edu/esys/resources/program-forms-guides
Terms: Win, Spr | Units: 2

EARTHSYS 213: Hacking for Climate and Sustainability

The challenges of addressing climate change and sustainability require urgency as well as innovative solutions. Startups operate with speed and urgency, 24/7. In recent years they have learned not only how to effectively innovate but also how to be extremely efficient with resources and time, using lean startup methods. Participants in this class develop the skills required of a mission driven entrepreneur by tackling a critical problem in climate and sustainability as part of a team of engineers, scientists, social scientists, MBAs, and law and policy experts. Teams will engage pressing climate and sustainability problems and learn how to apply lean startup principles ("business model canvas," "customer development," and "agile engineering") in developing solutions. Students will take a hands-on, experiential approach to explore options for solutions and needs for stakeholders. The process of exploring options will require participants to engage deeply and to learn how to work closely more »
The challenges of addressing climate change and sustainability require urgency as well as innovative solutions. Startups operate with speed and urgency, 24/7. In recent years they have learned not only how to effectively innovate but also how to be extremely efficient with resources and time, using lean startup methods. Participants in this class develop the skills required of a mission driven entrepreneur by tackling a critical problem in climate and sustainability as part of a team of engineers, scientists, social scientists, MBAs, and law and policy experts. Teams will engage pressing climate and sustainability problems and learn how to apply lean startup principles ("business model canvas," "customer development," and "agile engineering") in developing solutions. Students will take a hands-on, experiential approach to explore options for solutions and needs for stakeholders. The process of exploring options will require participants to engage deeply and to learn how to work closely with policy makers, technologists, government officials, NGOs, foundations, companies, and others interested in solving these problems, while demanding that teams continually build iterative prototypes to test their understanding of the problem and solution hypotheses. For more information on problems and sponsors as they are added and to apply for the course, see  https://h4cs.stanford.edu/. Applications required in November. Limited enrollment. https://earth.stanford.edu/esys/resources/program-forms-guides
Terms: Win | Units: 3

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

EARTHSYS 220: Environmental Justice in California (EARTHSYS 120)

Although California is considered a National policy leader in environmental justice, communities across the state struggle for basic environmental rights. Through lectures, readings, and field trips, this course will analyze this contradiction by examining the development of environmental justice movements and environmental justice policy in California. The course will explore how California's political, social, and economic histories inform environmental justice struggles. We will study specific and intersecting challenges facing African American, Indigenous, Latinx, and AAPI communities. This course will include an introduction to theories, such as de-growth and Municipalism, applied in strategies for environmental justice; as well as, analyses of topics ranging from agricultural labor, incarceration, extractive industries, and environmental justice in Silicon Valley.
Terms: Win | Units: 3
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