This course is an introductory subject in the field of electric power systems and electrical to mechanical energy conversion. Electric power has become increasingly important as a way of transmitting and transforming energy in industrial, military and transportation uses. Electric power systems are also at the heart of alternative energy systems, including wind and solar electric, geothermal and small scale hydroelectric generation.

During this course, we will be exploring basic questions of architecture through several short design exercises. Working with many different media, students will discover the interrelationship of architecture and its related disciplines, such as structures, sustainability, architectural history and the visual arts. Each problem will focus on one of these disciplines and one exploration and presentation technique.

Frameworks and Models for Technology and Policy students explore 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 for Technology and Policy students 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. 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.

1.201J/11.545J/ESD.210J is required for all first-year Master of Science in Transportation students. It would be of interest to, as well as accessible to, students in Urban Studies and Planning, Political Science, Technology and Policy, Management, and various engineering departments. It is a good subject for those who plan to take only one subject in transportation and serves as an entry point to other transportation subjects as well. The subject focuses on fundamental principles of transportation systems, introduces transportation systems components and networks, and addresses how one invests in and operates them effectively. The tie between transportation and related systems is emphasized.

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

The learning of linear functions is pervasive in most algebra classrooms. Linear functions are vital in laying the foundation for understanding the concept of modeling. This unit gives students the opportunity to make use of linear models in order to make predictions based on real-world data, and see how engineers address incredible and important design challenges through the use of linear modeling. Student groups act as engineering teams by conducting experiments to collect data and model the relationship between the wall thickness of the latex tubes and their corresponding strength under pressure (to the point of explosion). Students learn to graph variables with linear relationships and use collected data from their designed experiment to make important decisions regarding the feasibility of hydraulic systems in hybrid vehicles and the necessary tube size to make it viable.

Students learn how the sun can be used for energy. They learn about passive solar heating, lighting and cooking, and active solar engineering technologies (such as photovoltaic arrays and concentrating mirrors) that generate electricity. Students investigate the thermal energy storage capacities of test materials. They learn about radiation and convection as they build a model solar water heater and determine how much it can heat water in a given amount of time. In another activity, students build and compare the performance of four solar cooker designs. In an associated literacy activity, students investigate how people live "off the grid" using solar power.

Students learn how energy consumption has changed over the past 100 years, why it has changed, and the impact it has had. Students brainstorm and categorize uses of energy, take part in an optional consumption simulation, interpret graphs about energy use, take surveys, and engage in small group and classroom discussions about energy comparisons.

The advantages and disadvantages of different kinds of non-renewable energy sources are the focus of this lesson. Students match different kinds of energy resources with their advantages and disadvantages, and then discuss whether these advantages and disadvantages are economic,ecological, or social. As an extension students identify the environmental impacts of their family’s electricity usage using EPA’s Power Profiler web site. The next lesson will deal with renewable resources.

The focus of this lesson is learning about the advantages and disadvantages of different kinds of renewable energy resources and their potential use in Michigan. Students read about different renewable resources, watch a teacher demonstration, and match different kinds of energy sources with the advantages and disadvantages of each. Students then compare the advantages and disadvantages of renewable and non-renewable resources and use the comparisons to write a letter to their state legislators.

This course is a required sophomore subject in the Department of Materials Science and Engineering, designed to be taken in conjunction with the core lecture subject 3.012 Fundamentals of Materials Science and Engineering. The laboratory subject combines experiments illustrating the principles of quantum mechanics, thermodynamics and structure with intensive oral and written technical communication practice. Specific topics include: experimental exploration of the connections between energetics, bonding and structure of materials, and application of these principles in instruments for materials characterization; demonstration of the wave-like nature of electrons; hands-on experience with techniques to quantify energy (DSC), bonding (XPS, AES, FTIR, UV/vis and force spectroscopy), and degree of order (x-ray scattering) in condensed matter; and investigation of structural transitions and structure-property relationships through practical materials examples.

Objective
SWBAT examine personal use of energy as measured in kilowatts by creating a spreadsheet to easily analyze data.

Big Idea
How much energy do we really use? Authentic technology integration is supported in the lesson as students create an Excel spreadsheet to analyze data. Students analyze the spreadsheet to determine a personal contribution to climate change.

Parallel treatments of photons, electrons, phonons, and molecules as energy carriers, aiming at fundamental understanding and descriptive tools for energy and heat transport processes from nanoscale continuously to macroscale. Topics include the energy levels, the statistical behavior and internal energy, energy transport in the forms of waves and particles, scattering and heat generation processes, Boltzmann equation and derivation of classical laws, deviation from classical laws at nanoscale and their appropriate descriptions, with applications in nano- and microtechnology.

The People's Physics Book v3 is intended to be used as one small part of a multifaceted strategy to teach physics conceptually and mathematically

PhET provides fun, free, interactive, research-based simulations for math and science. The simulations are written in HTML5, and can be used online or downloaded to your computer. This is free for all students and teachers. There are hundreds of lesson plans and materials using the simulations.

Objective
Students will be able to use interactive visualizations, exploring how light energy is transformed into chemical energy and stored in glucose during photosynthesis.

Big Idea
Plants make their own food.

Objective
Students will be able to demonstrate their understanding of photosynthesis

Big Idea
Show what you know!

Objective
Students will be able to read and understand the formula for photosynthesis.

Big Idea
A chemical equation is a model for a reaction that happens in real life.

Objective
Students will be able to discover basic ideas about photosynthesis.

Big Idea
Where does the mass of a tree come from?