Students investigate the property dependence between liquid and solid interfaces and determine observable differences in how liquids react to different solid surfaces. They compare copper pennies and plastic "coins" as the two test surfaces. Using an eye dropper to deliver various fluids onto the surfaces, students determine the volume and mass of a liquid that can sit on the surface. They use rulers, scales, equations of volume and area, and other methods of approximation and observation, to make their own graphical interpretations of trends. They apply what they learned to design two super-surfaces (from provided surface treatment materials) that arecapable of holding the most liquid by volume and by mass. Cost of materials is a parameter in their design decisions.

The sensing, thinking, moving body is the basis of our experience in the world; it is the very foundation on which cognitive intelligence is built. Physical Intelligence, then, is the inherent ability of the human organism to function in extraordinary accord with its physical environment. This class–a joint offering from the Department of Athletics, Physical Education and Recreation (DAPER) and Department of Mechanical Engineering (ME) for both PE and academic credit–uses the MIT gymnastics gym as a laboratory to explore Physical Intelligence as applied to Mechanical Engineering and design. Readings, discussions and experiential learning introduce various dimensions of Physical Intelligence which students then apply to the design of innovative exercise equipment.

Students learn the fundamentals of using microbes to treat wastewater. They discover how wastewater is generated and its primary constituents. Microbial metabolism, enzymes and bioreactors are explored to fully understand the primary processes occurring within organisms.

Students will explore the outdoor classroom in pairs looking for evidence of animal life and imagining what types of animals might live in, and survive in, the outdoor classroom area.

No matter where you live, there are things to observe in the night sky. In this episode learn how you can become a night sky observer.

How can you safely view the August 21 solar eclipse? What is a solar eclipse? Where can you see this upcoming eclipse?

This course offers a broad overview of physical, chemical, biological, geological, principles of environmental sciences, and serves as a core course for EEOS majors. Examples will focus on linked watershed and coastal marine systems. The student will be introduced to natural processes and interactions in the atmosphere, in the ocean, and on land. There is a focus on biogeochemical cycling of elements as well as changes of these natural cycles with time, especially with recent anthropogenic effects. Topics include plate tectonics, global climate change, ozone depletion, water pollution, oceanography, ecosystem health, and natural resources.

This web page is an interactive physics problem on vector addition. The page explains the concept of breaking a vector into components and adding them together, and works through an example problem. The attached Java applet visualizes the problem. This is part of a collection of similar simulation-based student activities.

A PBL project I did in my HS physics and math classes to allow students voice & choice in the design of a maker space my school was building. It followed the Buck Institute model and allowed students to prove mastery in a varitey of learning targets per topics in both courses (probability, geometry, functions, algebra, and trig in geometry and force, energy, electricity & magnetism, etc. in physics). Please feel free to remix this project to suit your own needs.

This lesson is designed to educate students of the importance of the inclusion of physical activity in their daily routines, and ways to increase this at school, during times other than recess.

Play hockey with electric charges. Place charges on the ice, then hit start to try to get the puck in the goal. View the electric field. Trace the puck's motion. Make the game harder by placing walls in front of the goal. This is a clone of the popular simulation of the same name marketed by Physics Academic Software and written by Prof. Ruth Chabay of the Dept of Physics at North Carolina State University.

Interactive Video Vignettes (IVVs) are ungraded web-based assignments for introductory physics students. They combine the convenience of online video with video analysis and the interactivity of individual tutorials. Each online vignette addresses a known learning difficulty. A typical vignette takes about 10 minutes or less to complete. It invites each student to make predictions, perform observations, and draw conclusions about a single phenomenon.

This tag related activity is for physical education classes in grades k-2. Students will be able to travel in different movement patterns, work together, and improve physical competency.

Did early Americans have to move west? This inquiry leads students through an investigation of Americans moving west. Students will learn about land use in America, the population change in America, and the Indian Removal Act of 1830. Resource created by Justin Bray, Fremont Public Schools, as part of the Nebraska ESUCC Social Studies Special Projects 2023 Inquiry Design Model (IDM).

This series of two lessons uses cutting-edge scientific research on the effects of climate change on communities in the intertidal. Through a combination of a dynamic presentation and several videos, students are introduced to the effects of climate change on the ocean (ocean acidification and temperature increase) and what is known about how ocean organisms are affected. Then students read and interpret graphs and construct a scientific explanation based on data from this research.

An interactive lecture demonstration intended to help students use physics reasoning to predict the outcome of a puzzling electrostatics demonstration.

Design and engineer a mechanical device that is powered by hydraulic (syringe and water) that includes levers and moving parts that will propel a ping pong ball to complete the 2 levels of the “Hoop Shoot Challenge”.

Students learn about floods, discovering that different types of floods occur from different water sources, but primarily from heavy rainfall. While floods occur naturally and have benefits such as creating fertile farmland, students learn that with the increase in human population in flood-prone areas, floods are become increasingly problematic. Both natural and manmade factors contribute to floods. Students learn what makes floods dangerous and what engineers design to predict, control and survive floods.

Students work in teams of two to discover the relative positions of the Earth, Sun and Moon that produce the different phases of the Moon. Groups are each given a Styrofoam ball that they attach to a pencil so that it looks like a lollipop. In this acting-out model exercise, this ball on a stick represents the Moon, the students represent the Earth and a hanging lightbulb serves as the Sun. Students move the "Moon" around them to discover the different phases. They fill in the position of the Moon and its corresponding phase in a worksheet.