Students examine how the orientation of a photovoltaic (PV) panel relative to the sun affects the efficiency of the panel. Using sunshine (or a lamp) and a small PV panel connected to a digital multimeter, students vary the angle of the solar panel, record the resulting current output on a worksheet, and plot their experimental results.

This video describes how Colorado has planned for and uses clean energy resources to reduce its carbon footprint.

This customized independent study course puts Sloan Fellows MBA students into direct contact with innovators tackling global needs in education, healthcare, and energy/environment. Co-designed projects address low-income markets in the U.S. or globally, focusing on the application of new ideas and technology rooted in MIT innovations or the Boston ecosystem. Every project aims to develop better ways for the right innovations to reach scale, sustainability, and quality, thereby improving lives and uncovering opportunities in underserved markets.

In this lesson, students will explore motion, rockets and rocket motion while assisting Spacewoman Tess, Spaceman Rohan and Maya in their explorations. They will first learn some basic facts about vehicles, rockets and why we use them. Then, the students will discover that the motion of all objects including the flight of a rocket and movement of a canoe is governed by Newton's three laws of motion.

In this high school physical sciences unit, students investigate why some substances absorb heat when they react, while others release it. Students first solve the mystery of where the energy goes in endothermic reactions by examining salt dissolution and using magnets as models for bonds. They then expand their investigations to look into where the energy comes from in exothermic reactions. The model they continue to develop using magnets, helps them account for why breaking bonds absorbs energy from the surroundings and forming bonds releases energy back into the surroundings. The end of the unit naturally motivates a new question to pursue in future units, “Why are some types of particles more attracted to one another than others?"

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Infrastructures for energy, water, transport, information and communications services create the conditions for livability and economic development. They are the backbone of our society. Similar to our arteries and neural systems that sustain our human bodies, most people however take infrastructures for granted. That is, until they break down or service levels go down.

In many countries around the globe infrastructures are ageing. They require substantial investments to meet the challenges of increasing population, urbanization, resource scarcity, congestion, pollution, and so on. Infrastructures are vulnerable to extreme weather events, and therewith to climate change.
Technological innovations, such as new technologies to harvest renewable energy, are one part of the solution. The other part comes from infrastructure restructuring. Market design and regulation, for example, have a high impact on the functioning and performance of infrastructures.

Students will participate travel from station to station modeling how nitrogen cycles through an ecosystem. This is relevant for students to understand how the matter on earth is finite (conservation of matter), but it can be transferred from place to place and in different forms. Nitrogen is a vital component of life and how we live.

Students describe the basic principles of nuclear chemistry, discern between diagrams and representations of nuclear equations and processes, and use context clues to correctly categorize nuclear events.

Students learn about nuclear energy generation through a nuclear power plant virtual field trip that includes visiting four websites and watching a short video taken inside a nuclear power plant. They are guided by a handout that provides the URLs and questions to answer from their readings. They conclude with a class discussion to share their findings and reflections. It is recommended that students complete the associated activity, Chernobyl Empathy, before conducting this lesson; doing this assists students in gaining an understanding of how devastating nuclear meltdowns can be, which underscores the importance of careful engineering.

SYNOPSIS: In this lesson, students research nuclear energy and advocate for its expansion or contraction in order to meet the goals of the Paris Agreement. Students form policy proposals and compromise on the best path forward.

SCIENTIST NOTES: This lesson enables students to understand the advantages and disadvantages of nuclear energy, particularly the fission process. They would also analyze the best energy plans and develop policy proposals that would achieve the Paris goal and address climate change. All activities and materials have been fact-checked, and this lesson is recommended for teaching.

POSITIVES:
-Students explore a topic that is relevant but may not be part of their daily routine.
-Students collaborate in research and discussion.
-Students have the opportunity to choose what to research.
-Students have the opportunity to discuss opposing arguments in a civil and productive way. Students must listen to one another to compromise on an energy policy.
-This lesson provides a grading rubric.

ADDITIONAL PREREQUISITES:
-Students can design local, national, or global policy proposals.
-Allow students to discuss freely and independently; offer guidance only when students appear off track or stuck.
-Make sure everyone has an opportunity to contribute to each group conversation.
-It may be necessary to coach your students on how to be a respectful listener. This includes making eye contact and refraining from looking at screens.
-This lesson can be split into multiple sessions or days. Parts of this lesson can also be assigned to be completed outside of regular class time.

DIFFERENTIATION:
-The extent of student research and detail in policy planning can be adjusted to student skill level.
-If your class has 24 students, you may have eight groups of students. Four of the groups would advocate for expanding nuclear energy capacity, and four of the groups would advocate for reducing nuclear energy capacity.
-It may be necessary to ask some students to take opposing viewpoints in order to have a balanced class. For example, if 19 of your 24 students want to expand nuclear energy capacity, some of them will have to switch sides in order to create more balance. It may be helpful to emphasize the fact that people with strong debating skills can argue both sides of any argument.

"Nuclear Power Plant Calculations" serves as a seamless continuation of the educational unit on "Introduction to Nuclear Reactors." This comprehensive resource is tailored for engineering students specializing in nuclear power, aiming to deepen their understanding of reactor dynamics and operational efficiency. Through structured lessons, learners explore fundamental concepts such as reactor power output, fuel efficiency, and core temperature regulation, building upon the foundational principles established in the previous unit. Practical problem-solving exercises are integrated throughout the resource, allowing students to apply theoretical knowledge to real-world scenarios.

This video segment adapted from FRONTLINE looks at nuclear fission as an energy source that can be used to generate electricity.

Problems in nuclear engineering often involve applying knowledge from many disciplines simultaneously in achieving satisfactory solutions. The course will focus on understanding the complete nuclear reactor system including the balance of plant, support systems and resulting interdependencies affecting the overall safety of the plant and regulatory oversight. Both the Seabrook and Pilgrim nuclear plant simulators will be used as part of the educational experience to provide as realistic as possible understanding of nuclear power systems short of being at the reactor.

The MIT Nuclear Weapons Education Project aims to teach individuals, particularly those who grew up after the end of the Cold War, about what nuclear weapons are and their effects on the world. The project website provides materials for lectures or discussions at introductory course levels.

This course was designed to educate students about how nuclear weapons came into being, the physics of these weapons, how they are structured, how they have evolved over the past several decades, efforts to control them and limit the threats that they represent, and what the possibilities for the future are. Many people in our country and other countries are not aware of what an existential threat nuclear weapons represent, and this lack of awareness is an important part of the overall threat. 
The course was taught by an MIT Iterdisciplinary team coordinated by Robert P. Redwine, Professor of Physics Emeritus.  The full list of instructors is listed on the course page.

This video segment adapted from Shedding Light on Science illustrates how light changes speed, and thus direction, in a process known as refraction.

The subject introduces the principles of ocean surface waves and their interactions with ships, offshore platforms and advanced marine vehicles. Surface wave theory is developed for linear and nonlinear deterministic and random waves excited by the environment, ships, or floating structures.
Following the development of the physics and mathematics of surface waves, several applications from the field of naval architecture and offshore engineering are addressed. They include the ship Kelvin wave pattern and wave resistance, the interaction of surface waves with floating bodies, the seakeeping of ships high-speed vessels and offshore platforms, the evaluation of the drift forces and other nonlinear wave effects responsible for the slow-drift responses of compliant offshore platforms and their mooring systems designed for hydrocarbon recovery from large water depths.
This course was originally offered in Course 13 (Department of Ocean Engineering) as 13.022. In 2005, ocean engineering subjects became part of Course 2 (Department of Mechanical Engineering), and this course was renumbered 2.24.

This lesson focuses on the importance of ocean exploration as a way to learn how to capture, control, and distribute renewable ocean energy resources. Students begin by identifying ways the ocean can generate energy and then research one ocean energy source using the Internet. Finally, students build a Micro-Hydro Electric Generator.

This course makes students familiar with the design of offshore wind farms in general and focuses on the foundation design in particular. The course is based on actual cases of real offshore wind farms that have been built recently or will be built in the near future.

Students learn and discuss the advantages and disadvantages of renewable and non-renewable energy sources. They also learn about our nation's electric power grid and what it means for a residential home to be "off the grid."