This course focuses on national environmental and energy policy-making; environmental ethics; the techniques of environmental analysis; and strategies for collaborative environmental decision-making. The primary objective of the course is to help students formulate a personal theory of environmental planning practice. The course is taught comparatively, with constant references to examples from around the world. It is required of all Graduate / Professional students pursuing an environmental policy and planning specialization in the Department of Urban Studies and Planning at MIT. This course is the first subject in the Environmental Policy and Planning sequence. It reviews philosophical debates including growth vs. deep ecology, "command-and-controlâ€ vs. market-oriented approaches to regulation, and the importance of expertise vs. indigenous knowledge. Emphasis is placed on environmental planning techniques and strategies. Related topics "include the management of sustainability, the politics of ecosystem management, environmental governance and the changing role of civil society, ecological economics, integrated "assessment (combining environmental impact assessment (EIA) and risk assessment), joint fact finding in science-intensive policy disputes, environmental justice in poor communities of "color, and environmental dispute resolution. "Environmental Problem-Solving "(Susskind et al., 2017, Anthem Press), a video-enhanced eBook, provides students with full access to all the "assigned readings, faculty commentary on the readings, and examples of the best student performance on course assignments in previous years.

This course begins by introducing students to aspects of fluid dynamics relevant to transport and deposition of particulate sedimentary materials. Emphasis is on the structure of turbulent shear flows and the forces exerted by fluid motions on bed of loosed sediment. With fluid dynamics as background, the course deals with sediment movement as bed load and suspended load, and with the geometry, kinematics, and dynamics of ripple and dune bed forms. The course concludes with basic material on the styles of current-generated primary sedimentary structures, with emphasis on cross stratification.

Introduction to landforms using landforms from around the world. Read a fictional book, then present images of landforms from different countries. The provided Google Slides presentation can be copied and edited to suit your class. 

This subject provides an introduction to modeling and simulation, covering continuum methods, atomistic and molecular simulation, and quantum mechanics. Hands-on training is provided in the fundamentals and applications of these methods to key engineering problems. The lectures provide exposure to areas of application based on the scientific exploitation of the power of computation. We use web based applets for simulations, thus extensive programming skills are not required.

Introduction to Oscillations and Waves covers the basic mathematics and physics of oscillatory and wave phenomena. By the end of the course, students should be able to explain why oscillations appear in many near equilibrium systems, the various mathematical properties of those oscillations in various contexts, how oscillations and waves are related, and the basic mathematical description and properties of a wave.
This course was offered as part of MITES Summer, a six-week, residential STEM experience for rising high school seniors. MIT Introduction to Technology, Engineering, and Science (MITES) provides transformative experiences that bolster confidence, create lifelong community, and build an exciting, challenging foundation in STEM for highly motivated 7th–12th grade students from diverse and underrepresented backgrounds.

This set of 10 lectures (about 11+ hours in duration) was excerpted from a three-day course developed at MIT Lincoln Laboratory to provide an understanding of radar systems concepts and technologies to military officers and DoD civilians involved in radar systems development, acquisition, and related fields. That three-day program consists of a mixture of lectures, demonstrations, laboratory sessions, and tours.
Online Publication

This introductory course from the FOSTER Consortium (supported by the European Union's Seventh Framework Programme for research, technological development and demonstration and the European Union's Horizon 2020 programme) will help you to understand what Responsible Research & Innovation (RRI) means, where it has come from, and why it can introduce an important and beneficial shift in relations between research, innovation and citizens.

Upon completing the course you will:

Understand what RRI means
Understand the reasons why the term RRI and related practices have emerged
Know about opportunities RRI can provide & obstacles you may face
Know the basics of how to start practicing RRI as a researcher and as an institution/industry

Introduction to Statistical Physics introduces the concepts and formalism at the foundations of statistical physics. By the end of the course, students should understand qualitative and quantitative definitions of entropy, the implications of the laws of thermodynamics, and why the Boltzmann distribution is important in modeling systems at finite temperature. In terms of skills, students should have increased their familiarity with mathematical methods in the physical science, learned how to write short programs to simulate random events, and become more adept at articulating their understanding of physics.
This course was offered as part of MITES Summer, a six-week, residential STEM experience for rising high school seniors. MIT Introduction to Technology, Engineering, and Science (MITES) provides transformative experiences that bolster confidence, create lifelong community, and build an exciting, challenging foundation in STEM for highly motivated 7th–12th grade students from diverse and underrepresented backgrounds.

This class assesses current and potential future energy systems, covering resources, extraction, conversion, and end-use technologies, with emphasis on meeting regional and global energy needs in the 21st century in a sustainable manner. Instructors and guest lecturers will examine various renewable and conventional energy production technologies, energy end-use practices and alternatives, and consumption practices in different countries. Students will learn a quantitative framework to aid in evaluation and analysis of energy technology system proposals in the context of engineering, political, social, economic, and environmental goals. Students taking the Graduate / Professional version, Sustainable Energy, complete additional assignments.

This course explores perspectives in the policy process - agenda setting, problem definition, framing the terms of debate, formulation and analysis of options, implementation and evaluation of policy outcomes using frameworks including economics and markets, law, and business and management. Methods include cost/benefit analysis, probabilistic risk assessment, and system dynamics. Exercises include developing skills to work on the interface between technology and societal issues; simulation exercises; case studies; and group projects that illustrate issues involving multiple stakeholders with different value structures, high levels of uncertainty, multiple levels of complexity; and value trade-offs that are characteristic of engineering systems. Emphasis on negotiation, team building and group dynamics, and management of multiple actors and leadership.

Introduction to the Modeling and Analysis of Complex Systems introduces students to mathematical/computational modeling and analysis developed in the emerging interdisciplinary field of Complex Systems Science. Complex systems are systems made of a large number of microscopic components interacting with each other in nontrivial ways. Many real-world systems can be understood as complex systems, where critically important information resides in the relationships between the parts and not necessarily within the parts themselves. This textbook offers an accessible yet technically-oriented introduction to the modeling and analysis of complex systems. The topics covered include: fundamentals of modeling, basics of dynamical systems, discrete-time models, continuous-time models, bifurcations, chaos, cellular automata, continuous field models, static networks, dynamic networks, and agent-based models. Most of these topics are discussed in two chapters, one focusing on computational modeling and the other on mathematical analysis. This unique approach provides a comprehensive view of related concepts and techniques, and allows readers and instructors to flexibly choose relevant materials based on their objectives and needs. Python sample codes are provided for each modeling example.

This is a lesson plan for introductory science in the preschool classroom. Its an activity about the sun and the sun's effects on the earth. It includes a song, lecture, story time, poster creation, and student presentation.

This animation from KET's distance learning physics course demonstrates the mathematical formula for a scientific law as it applies to light.

In this inquiry-based lesson, students will investigate how rainfall changes the land and causes runoff. The students will simulate a stream table to show how rainfall erodes the land. This lesson results from a collaboration between the Alabama State Department of Education and ASTA.

This lesson will begin with students discussing ways that we can feel the sun's energy even though the sun is very far away from Earth. Then, the teacher will introduce the three methods of heat transfer (radiation, conduction, and convection) utilizing an online video clip, and the students will take jot notes while viewing the video clip. Next, the students will perform an experiment to investigate radiation as a form of heat transfer by recording how the temperature of ice changes when exposed to an energy source (solar energy or heat energy from a clamp lamp). Then, students will perform an experiment to investigate convection as a form of heat transfer using blue dyed ice cubes and warmed red food coloring, to create a convection cycle within a container filled with room-temperature water. Lastly, students will apply the data gathered from the experiments to write a response to the question: "How is heat energy from the sun distributed between Earth's surface and the atmosphere?" This lesson results from the ALEX Resource Gap Project.

Students use media resources and an in-class investigation to explore the types of energy within different types of systems. They also use the formulas for kinetic and potential energy to examine the path of a projectile.

This lesson provides an introductory-level experience with soil. During the experiment, students will combine soil with water and conduct observations. The observations made will lead to greater understanding of soil's basic properties. This lesson results from a collaboration between the Alabama State Department of Education and ASTA.

In this video segment adapted from ZOOM, the cast builds a suspension bridge from a couple of chairs, some cardboard, and rope.

In this video segment adapted from NOVA, a scientist explains the unexpected heat source fueling widespread volcanic activity on Io, a moon of Jupiter that many had previously assumed to be frozen.