The basic physical science principles of gravitational force and air resistance are explored as students design, build, test, and evaluate parachutes. K-W-L charts are used to assess students’ knowledge of the engineering design process and the scientific method. The book, “Mercedes and the Chocolate Pilot” by Margot Theis Ravin, is read to students and they discuss whether the pilot acted like an engineer as he wanted to share sweets with children during the Berlin Airlift. The students are presented with a problem, getting food and water to islanders whose homes and roads have been damaged by hurricanes. Simple materials such as paper napkins, paper towels, crocheting thread, and paper clips are used to build the parachutes. The students use the five ‘E’s’: engagement, exploration, explanation, evaluation, and elaboration as they compare their various parachute models. Students learn that air contains particles, and it is these particles that place forces on bodies moving in the air and counteract the force of gravity. Students use math in the analysis of their models. Students learn that models representing parachutes can be designed in many ways and may behave differently when tested. Students learn the many ways engineering and science are used to explore and explain nature and are employed in manufacturing and technology processes.

TAKEAWAYS:
Student groups learn that the engineering design process and the scientific method are circular processes as they design, build, test, and evaluate a parachute model then improve it.

SPEAKERS:
Suzanne Cunningham (Purdue University: West Lafayette, IN)

This session will introduce participants to the Exploration Generation Middle School NSTA Playlist. It provides equitable STEM experiences to students and increases educator confidence in teaching rocketry. This two-lesson playlist brings Sensemaking to rocketry by cultivating student curiosity about rockets to drive learning about science ideas related to physics topics. Participants will investigate forces through hands-on engagement, while also learning about rocket safety. Learn how to develop critical skills within your students to prepare them for the careers of tomorrow.

TAKEAWAYS:
The excitement and curiosity generated by model rocket launches can be used to drive student learning about a variety of physical science ideas.

SPEAKERS:
Michelle Phillips (NSTA: Arlington, VA), Patrice Scinta (NSTA: Arlington, VA), Nicole Bayeur (Estes Industries: , United States)

This session introduces a way to create learning experiences that are meaningful, rigorous, and equitable for students. Participate in the same sort of rich and meaningful learning experiences that are called for by the NGSS.

TAKEAWAYS:
The characteristics of learning experiences that are meaningful, relevant, and equitable for students and how to give students an opportunity to use their own ideas along with the DCIs, CCs, and SEPs in the service of sensemaking during these experiences.

SPEAKERS:
Todd Hutner (The University of Alabama: Austin, TX)

Participants will design and test a vessel that will land an egg dropped from a substantial heights without breaking the egg. Participants will use a variety of materials to provide the softest landing possible. Participants will employ technology to assist them in designing their vessels and shape their final methods.

TAKEAWAYS:
Design and test an egg vessel with real time data. Analyze live data to better design a successful egg drop vessel. Experience the engineering design process. - Using technology to test prototypes. -employing the engineering design process. -applying modern technology to past challenges.

SPEAKERS:
Brad Posnanski (Comsewogue High School: Port Jefferson Station, NY), Todd Graba (Crystal Lake South High School: Crystal Lake, IL)

Each attendee will receive materials and instructions to construct a Higgs Boson. Dice and investigative procedure are included to determine the mass of six quarks.

TAKEAWAYS:
1. How to take an abstract concept and create concrete hands-on investigations; 2. Suggestions to go from teacher-centered to a student centered-curriculum; and 3. The importance of looking for trends, patterns, and regularities for modeling.

SPEAKERS:
Gary Schiltz (Retired Chemistry Teacher: Naperville, IL)

The first 50 attendees will be be given the materials (circluar rings, rulers, and paper) to model the Doppler effect. Attendees will need a calculator for the quantitative portion of the workshop.

TAKEAWAYS:
1. How to take an abstract concept and create a concrete hands-on investigation; 2. Suggestions to go from teacher-centered to a student centered-curriculum; and 3. The importance of looking for trends, patterns, and regularities for modeling.

SPEAKERS:
Gary Schiltz (Retired Chemistry Teacher: Naperville, IL)

Students are generally intrigued by cosmology but it can be difficult for instructors to explain. For some scientists and teachers, the famous Hubble graph from which we obtain Hubble’s Law makes it obvious that the universe is expanding but for most students (and many of us teachers!) this is not the case: looking at the graph does not obviously imply an expanding universe. We will discuss standard candles and the redshifting of light, and how Hubble used these to measure the speeds and distances to galaxies. We will examine his data and graph and then we will work through an activity that will help students see why the 1929 graph implies an expanding universe. The simple activity uses elastic and rulers and provides a qualitative introduction to the Hubble redshift. Additionally, we will share other ideas and materials for teaching students about cosmology and the expansion of the universe.

TAKEAWAYS:
Students can produce a Hubble-like graph representing an expanding universe using elastic and a ruler.

SPEAKERS:
Todd Brown (University of Pittsburgh at Greensburg: Greensburg, PA)

This session highlights an activity from NASA’s Learning Launchers: Robotics (https://www.nasa.gov/audience/foreducators/stem-on-station/learning_launchers_robotics) teacher toolkit part of a series of Educator Guides with lessons and activities to help bring the International Space Station into the classroom. This session will focus on the “I Want to Hold Your Hand” activity that engages participants to build and test a robotic-like hand and understand how NASA uses robotic explorers to collect information about places where humans cannot travel. After watching videos "Robotics and the International Space Station" & "Benefits For Humanity: From Space to Surgery" participants will work in teams to construct a robotic-like hand and test their robotic hand by picking up an empty soda can or other lightweight objects. The “I Want to Hold Your Hand Activity” is aligned to national standards for science, technology, engineering, and mathematics (STEM) (i.e., NGSS, ISTE). The focus of the “I Want to Hold Your Hand” activity ties Engineering Design and NGSS science and engineering practices of defining problems, developing models, and planning and carrying out investigations. This session connects participants to how NASA uses robots in many ways as well as benefit humanity with its robots’ doing science and experiments aboard the International Space Station.

TAKEAWAYS:
1. Attendees will explore NASA STEM Educator Guides that are standards-aligned and provide detailed information and resources on how to implement NASA STEM engagement learning experiences in the classroom. 2. Attendees will gain hands-on minds-on experience with implementing a NASA STEM engagement activity in their classroom using everyday materials that encourages students to construct a robotic-like hand and demonstrate how data are collected when using robotic technology. 3. Attendees will gain insights into how humans and robots are working hand in hand to expand the horizons of space exploration and how robotic research that has helped make advances in medicine, auto manufacturing, among other things. Without robotics, major accomplishments like the building the International Space Station, repairing satellites in space, and exploring other worlds would not be possible.

SPEAKERS:
LaTina Taylor (NASA Educator Professional Development Collaborative (EPDC): Flossmoor, IL)

Attendees will be provided with a high-level overview of NASA’s Artemis Missions to the Moon and Mars, Next Generation Science Standards, and gain insights on how Engineering Design fits within the NGSS. This session highlights an activity from NASA’s Next Gen STEM - Moon to Mars Educator Guide titled, "Landing Humans on the Moon" (https://www.nasa.gov/stem-ed-resources/landing-humans-on-the-moon.html) which is part of a series of standards-aligned educator guides designed to help students reach their potential to join the next-generation STEM workforce and learn about sending humans to the Moon, Mars, and beyond. The focus of the “Safe Landing on the Lunar Surface” activity engages participants to understand how a spacecraft’s engines can provide downward thrust to counteract the force of gravity not only at launch, but also during a landing to slow its descent. Utilizing the engineering design process attendees will use household materials to better understand the difficulties in landing a lander on the surface of a terrestrial body that does not have an atmosphere (no atmospheric braking, no use of parachutes, and no aerodynamic control surfaces). Participants will design, build, and improve a model of a lunar lander that can slow its descent using the downward thrust of a balloon; graph the speed with respect to elevation of a model lunar lander.

TAKEAWAYS:
1. Attendee will explore NASA STEM Educator Guides that are standards-aligned and provide detailed information and resources on how to implement STEM engagement learning experiences in the classroom to help students learn about sending humans to the Moon, Mars, and beyond. 2. Attendees will gain hand on minds on experience with implementing NASA STEM engagement activities in their classroom. Then, using engineering design principles, attendees will mirror the process that NASA engineers follow to brainstorm a human lander design, ultimately building an actual model that they will test. 3. Participants will gain insights into the difficulties in landing a lander on the surface of a terrestrial body that does not have an atmosphere (no atmospheric braking, no use of parachutes, and no aerodynamic control surfaces).

SPEAKERS:
LaTina Taylor (NASA Educator Professional Development Collaborative (EPDC): Flossmoor, IL)

Turn any multiple-choice review into an exciting escape! Learn to create digital and in-person escapes to help keep students interested, engaged, and motivated.

TAKEAWAYS:
Participants will learn tips for designing escape boxes, plus how to add riddles, puzzles, games, and small prizes. The digital escape uses Google Forms, and the physical escape uses lockable boxes with resettable combination locks. Links to a customizable digital and physical escape will be available to attendees.

SPEAKERS:
Sharon Beck (Davidson County High School: Lexington, NC)

Did you know that every U.S. aircraft flying today, and every U.S. air traffic control facility, uses NASA-developed technology in some way? Participants in this session will gain insights into how NASA Aeronautics work to make aviation truly sustainable by reducing delays and environmental impacts, transforming aviation efficiency and safety, while reducing noise, fuel use, harmful emissions, and ultimately transform the way we fly. NASA’s X-57 Maxwell is an experimental aircraft designed to test operating multiple electric motors for use in turning propellers – an idea known as “distributed electric propulsion.” This session highlights an activity from NASA’s “X-57 Electric Airplane: STEM Learning Module” (https://www.nasa.gov/aeroresearch/stem/X57 ) part of a series of Educator Guides with lessons and activities to help students learn about NASA’s X-57 Maxwell and the science behind electric propulsion. This session will focus on the “X-57 Maxwell: Circuits Activity Guide” that engages participants to build a light-up paper helicopter by creating a “parallel circuit” that uses copper foil tape, two LED lights, and a battery. This session’s goals are to demonstrate that an all-electric airplane is more efficient, quieter, and more environmentally friendly. Session participants will understand that knowledge gained from the X-57 Maxwell research will help engineers design future electric-powered aircraft for everything from urban air mobility to moving passengers and cargo between nearby cities.

TAKEAWAYS:
1. Attendees will explore NASA STEM Educator Guides that are standards-aligned and provide detailed information and resources on how to implement NASA STEM engagement learning experiences in the classroom. 2. Hands-on minds-on experience with implementing a NASA STEM activity in their classroom that encourages students to create a parallel circuit on a paper helicopter as an introduction to circuitry and propulsion. 3. Attendees will gain insights into how NASA’s X-57 Maxwell all-electric airplane is more efficient, quieter, and more environmentally friendly while gaining a better understanding of the STEM concepts of energy transfer, and the physical science of pressure and aerodynamics.

SPEAKERS:
LaTina Taylor (NASA Educator Professional Development Collaborative (EPDC): Flossmoor, IL)