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Sphero Rocket Payload Mission
Grades:
9th Grade, 10th Grade, 11th Grade, 12th Grade
This lesson uses Sphero's "Rocket Payload" activity with the Outer Space Mat. The full lesson includes information on rocket payload, a Sphero coding challenge, a NASA link to read, optional questions
Grades:
4th Grade, 5th Grade, 6th Grade, 7th Grade, 8th Grade, 9th Grade, 10th Grade, 11th Grade, 12th Grade
Learn how to train your own Artificial Intelligence neural network without the complexities of coding. Google's (free) Teachable Machine is a web-based tool that makes it easy to train your computer
Grades:
9th Grade, 10th Grade, 11th Grade, 12th Grade
Description: Students will use Google’s TeachableMachine website to create an artificial intelligence image recognition model that recognizes various facial emotions (~4 facial expressions), such as
Grades:
6th Grade, 7th Grade, 8th Grade, 9th Grade, 10th Grade, 11th Grade, 12th Grade
Are your students fans of Formula 1? If they are or aren't this lesson will take a look into the dominance of Red Bull Racing in Formula 1. Why is Red Bull so dominant? Is it the driver or the
Grades:
7th Grade, 8th Grade, 9th Grade, 10th Grade, 11th Grade, 12th Grade
Students will use projectile motion as practical example to better understand how parabolas (quadratic equations) are built. Students will also tabulate x and y values on Google Spreadsheets and graph
Grades:
9th Grade, 10th Grade, 11th Grade, 12th Grade
Students pull wooden "sleds" with different masses on them over various types of surfaces with spring scales (force meters) to calculate the different coefficients of friction. Students graph the data
Grades:
9th Grade, 10th Grade, 11th Grade, 12th Grade
A high school physics lesson plan asking students to use guided inquiry and discover how current moves through series and parallel circuits. Students then share their results by using technology to
Grades:
9th Grade, 10th Grade, 11th Grade, 12th Grade
A high school physics lesson plan that uses guided inquiry to help students explore the changes in potential difference across resistors connected in series & parallel.
Grades:
7th Grade, 8th Grade, 9th Grade, 10th Grade, 11th Grade, 12th Grade
Dive into the physics and engineering and programming of holonomic drives! Learn to code and control movement for your FTC robot with hands-on activities and real-world applications.
Grades:
7th Grade, 8th Grade, 9th Grade, 10th Grade, 11th Grade, 12th Grade
This lesson is a whole unit on energy. It can be broken up into 10 separate lessons. I chose to put them all together so that it was easier to see how I organized them so you did not have to search
Grades:
8th Grade, 9th Grade, 10th Grade, 11th Grade, 12th Grade
A lesson designed for an engineering course but that can be used in a science course where we investigate the physics of waves and how it can be applied to the world of art. Students will design and
Grades:
Kindergarten, 1st Grade, 2nd Grade, 3rd Grade, 4th Grade, 5th Grade, 6th Grade, 7th Grade, 8th Grade, 9th Grade, 10th Grade, 11th Grade, 12th Grade
Button makers are great additions in the classroom! But first, students should learn the history of buttons, about the button machine and how to operate it. Challenge cards provided inspire students
Grades:
6th Grade, 7th Grade, 8th Grade, 9th Grade, 10th Grade, 11th Grade, 12th Grade
Students will pick an issue that they think exists in the world and propose a solution via a presentation. This will model a TedTalk.
Grades:
9th Grade, 10th Grade, 11th Grade, 12th Grade
This lesson can be used as a formative assessment on Static Equilibrium of a horizontal meter stick that has two masses hanging from the meter stick. One of the mass values is provided, the 2nd mass
Grades:
9th Grade, 10th Grade, 11th Grade, 12th Grade
This STEM Argumentative Research Project engages students in exploring the scientific, ethical, and societal implications of themes in Mary Shelley's "Frankenstein." Students will work in groups to
Grades:
7th Grade, 8th Grade, 9th Grade, 10th Grade, 11th Grade, 12th Grade
Students will apply principles of design, engineering, and mathematics to create a physical or digital labyrinth inspired by the myth of Theseus. This project integrates STEM concepts with literature
Grades:
10th Grade, 11th Grade, 12th Grade
This is part 2 of a two-part series. This lesson looks deeper into early electronic encryption tools and how they relate to cryptography today. The tools discussed are: Hebern Rotor Machine, Enigma
Grades:
9th Grade, 10th Grade, 11th Grade, 12th Grade
This lesson is a follow-up to the lesson titled "Creating Sustainable Solutions with Bioplastics Part 1". In this lesson, students evaluate different ingredients for bioplastics and create a minimum
Grades:
9th Grade, 10th Grade, 11th Grade, 12th Grade
In this lesson students evaluate the advantages and disadvantages of conventional, petroleum-based plastics, bioplastics, and their different varieties. The lesson is driven by class/group research
Grades:
7th Grade, 8th Grade, 9th Grade, 10th Grade, 11th Grade, 12th Grade
The students in this lab activity will play a competitive game with a small bouncy ball. The students will analyze the motion of the ball and apply projectile motion concepts. This activity requires
Grades:
10th Grade, 12th Grade
This lesson builds on the Part 1 of Urbanization Impacts in the HS Environmental Science classroom. In this lesson, students are utilizing their knowledge to create models of solutions to the
Grades:
9th Grade, 10th Grade, 11th Grade, 12th Grade
This lesson is an opportunity for students to learn about the past, the interesting field of nuclear radiation, and future implications to humanity as we encounter it in our spaces.
Grades:
7th Grade, 8th Grade, 9th Grade, 10th Grade, 11th Grade, 12th Grade
This is a lesson geared toward junior high and high school classes to introduce students to the idea of cryptography and encryption. This lesson could be simplified for younger students by removing
Grades:
9th Grade, 10th Grade, 11th Grade, 12th Grade
In this lesson, students physically manipulate a couple of springs and then collect data from a spring force Phet simulator. Next, they graph the data, calculate the area under the curve of their