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91 - 100 of 407 results for: CSI::certificate ; Currently searching offered courses. You can also include unoffered courses

DESINST 423: Design for Healthy Behavior Change

In the U.S., 75% of medical expenditures are for illnesses that are predominantly lifestyle related such as type 2 diabetes, arthritis and heart disease. It has been shown as people modify their lifestyles with healthier habits, medical problems can be reduced or avoided and a healthier and happier life achieved. The class employs design thinking in teams while working directly with volunteers in the community to help them achieve their health goals. There is an individual project and a team project each with multiple milestones. Learn and experience the design thinking process through interactions and design working within student teams and working directly with patient-volunteers from the practice of Drs. Ann Lindsay and Alan Glaseroff from the Stanford Coordinated Care Clinic. Admission by application. See dschool.stanford.edu/classes for more information.
Terms: Spr | Units: 3 | Grading: Letter (ABCD/NP)

EARTHSYS 101: Energy and the Environment (ENERGY 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. Recommended: MATH 21 or 42.
Terms: Win | Units: 3 | UG Reqs: GER:DB-EngrAppSci, WAY-AQR, WAY-SMA | Grading: Letter or Credit/No Credit

EARTHSYS 102: Fundamentals of Renewable Power (ENERGY 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. Recommended: Math 21 or 42.
Terms: Spr | Units: 3 | UG Reqs: GER:DB-EngrAppSci, WAY-SMA | Grading: Letter or Credit/No Credit

EARTHSYS 103: Understanding Energy (CEE 107A, CEE 207A)

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 more »
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 course is 4 units, which includes lecture and in-class discussion, readings and videos, assignments, and two off-site field trips. Field trip offerings differ each fall (see syllabus for updated list), but may include Diablo Canyon nuclear power plant, Shasta dam, Tesla Gigafactory, NextEra wind farm, San Ardo oil field, Geyser¿s geothermal power plants, etc. Students choose two field trips from approximately 8 that are offered. 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 (timing TBD). The 3-unit option requires instructor approval - please contact Diana Ginnebaugh. Open to all: pre-majors and majors, with any background! The course was formerly called Energy Resources. Website: http://web.stanford.edu/class/cee207a/ nFor a course that covers all of this but goes less in-depth into the technical aspects of each energy resource, check out CEE 107S/207S Understanding Energy: Essentials, offered spring and summer (cannot take both for credit). Prerequisites: Algebra. May not be taken for credit by students who have completed CEE 107S/207S or CEE 107E.
Terms: Aut | Units: 3-5 | UG Reqs: GER:DB-EngrAppSci, WAY-SI | Grading: Letter or Credit/No Credit

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

The economics of food production, consumption, and trade. The micro- and macro- determinants of food supply and demand, including the interrelationship among food, income, population, and public-sector decision making. Emphasis on the role of agriculture in poverty alleviation, economic development, and environmental outcomes. Grades based on mid-term exam and group modeling project and presentation. Enrollment is by application only and will be capped at 25, with priority given to upper level undergraduates in Economics and Earth Systems and graduate students (graduate students enroll in 206). Applications for enrollment are due by December 7, 2018. The application can be found here: https://economics.stanford.edu/academics/undergraduate-program/forms
Terms: Win | Units: 4 | UG Reqs: WAY-SI | Grading: Letter (ABCD/NP)

EARTHSYS 111: Biology and Global Change (BIO 117, 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 | Grading: Letter or Credit/No Credit

EARTHSYS 160: Sustainable Cities (URBANST 164)

Service-learning course that exposes students to sustainability concepts and urban planning as a tool for determining sustainable outcomes in the Bay Area. Focus will be on the relationship of 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 team-based projects in collaboration with local community partners and take part in significant off-site fieldwork. Prerequisites: consent of the instructor. (Cardinal Course certified by the Haas Center.)
Terms: Aut | Units: 4-5 | UG Reqs: WAY-ED, WAY-SI | Repeatable for credit | Grading: Letter or Credit/No Credit
Instructors: Chan, D. (PI)

EARTHSYS 180: Principles and Practices of Sustainable Agriculture (ESS 280)

Field-based training in ecologically sound agricultural practices at the Stanford Community Farm. Weekly lessons, field work, and group projects. Field trips to educational farms in the area. Topics include: soils, composting, irrigation techniques, IPM, basic plant anatomy and physiology, weeds, greenhouse management, and marketing. Application required. Deadline: September 12 for Autumn. nnApplication: https://stanforduniversity.qualtrics.com/jfe/form/SV_6Md7jndlBIcHV8V
Terms: Aut, Spr | Units: 3-4 | UG Reqs: GER: DB-NatSci, WAY-SMA | Repeatable for credit | Grading: Letter or Credit/No Credit

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: 4-5 | UG Reqs: WAY-AQR | Grading: Letter or Credit/No Credit
Instructors: Lobell, D. (PI)

EARTHSYS 188: Social and Environmental Tradeoffs in Climate Decision-Making (EARTHSYS 288)

How can we ensure that measures taken to mitigate global climate change don't create larger social and environmental problems? What metrics should be used to compare potential climate solutions beyond cost and technical feasibility, and how should these metrics be weighed against each other? How can modeling efforts and stakeholder engagement be best integrated into climate decision making? What information are we still missing to make fully informed decisions between technologies and policies? Exploration of these questions, alongside other issues related to potential negative externalities of emerging climate solutions. Evaluation of energy, land use, and geoengineering approaches in an integrated context, culminating in a climate stabilization group project.
Terms: Win | Units: 1-2 | Grading: Letter or Credit/No Credit
Instructors: Monroe, I. (PI)
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