The Universal Design for Learning (UDL) Guidelines are a tool that can be used to design learning experiences that meet the needs of all learners (CAST, 2018). Instructional designers and teachers can use these principles to create learning environments that reduce barriers to access for all students, while keeping in mind the learning goals of the lesson. The three guiding principles of UDL are engagement, representation, and action and expression. In this session educators will be provided with examples of these principles in action in sample materials from OpenSciEd and classroom videos. In these examples, participating will identify how the materials have been purposefully designed with multiple avenues for engagement, representation, and action and expression. Additionally, they will identify the built-in supports for teachers to highlight student assets and to address potential barriers to learning for their local student population. Teachers will utilize a tool to help them analyze their own lessons to identify goals, potential barriers, and ways to use the UDL Principles to remove barriers and create flexible paths to learning.

TAKEAWAYS:
Teachers will utilize a tool to help them analyze their own lessons to identify goals, potential barriers, and ways to use the UDL Principles to remove barriers and create flexible paths to learning.

SPEAKERS:
Sarah Delaney (OpenSciEd: San Carlos, CA)

After learning about computational thinking, participants will apply the framework to determine where students engage in computational thinking within the activity. Participants will engage in activities where students engineer as part of the investigations. Participants will be able to use a pre-programmed microcontroller (loaned by the presenters) to experience 3 different short investigations each tied to a different phenomenon. 1) Does angle matter? How does the angle of the collector affect how warm it is? Using the microcontroller and lamps participants will collect data to build a model that explains why the tilt of the Earth creates different seasons. 2) Transparent, Translucent, and Opaque. When working in a greenhouse, different materials can be used to cover the greenhouse. Which is the best material for your area? Using the light level sensor on the microcontroller, participants test different materials to recommend their uses when designing a greenhouse. 3) Making an alarm - using the microcontroller accelerometer sensor, participants arm an alarm and see how the accelerometer works in three dimensions. Participants will be provided printed copies of the lesson plans and how to engage students with using the microcontrollers. Note that no knowledge of coding or any equipment brought is necessary to participate in this workshop.

TAKEAWAYS:
Attendees will learn (1) Microcontrollers are small computers that come with several integrated sensors. Their functionality makes them useful for both investigations and engineering projects. Some of the basic functionality of different microcontrollers (2) One definition of computation thinking is how to use computers to solve problems. Computational thinking activities that connect students to everyday phenomena. The development of algorithms or the decomposition of problems into simple steps are just two examples of processes associated with computation thinking. It is a powerful problem-solving technique that is used in the modern world (3) How engineering tasks provide opportunities for student sensemaking

SPEAKERS:
Susan German (Hallsville Middle School: Hallsville, MO), G. Michael Bowen (Mount Saint Vincent University: Halifax, NS)

Introducing students to real-world engineering problems is a key component to engaging them in the science classroom. In this project, students solve the problem of saving pets from a hot car. Many students are aware of this issue and would have many ideas on how this could be achieved. This projects gives them the tools to help solve such a problem by building a model and finding a solution. Participants in this session will get to build the model themselves to see how information from sensors (input) can determine what should be done (output) through simple lines of code. No coding or engineering experience is needed, just imagination and logical thinking. Projects like these can expose students to STEM Careers. The exposure to coding and engineering design can also get them interested in doing more in the STEM field.

TAKEAWAYS:
Solve a real-work problem with coding and engineering design - no prior experience needed.

SPEAKERS:
Jessica Kohout (Independent Contractor: Ellicott City, MD), Stacy Thibodeaux (Southside High School: Youngsville, LA)

Human activities have caused changes in global temperature and weather patterns. This generation of students will need to understand climate science in order to adapt to this changing environment. In this session, participants will explore a project in which students incorporate engineering and basic coding - no experience necessary. We will use micro:bit technology to connect basic coding commands to collect authentic data using embedded sensors. Participants will use this collected data to modify design solutions based on human vulnerabilities to severe weather. Participants will find ways to expose their students to the engineering capabilities needed to solve problems. This project allows students to compare design solutions to identify which is best for the problem at hand and experience the interactive process of evaluating solutions. This project allows for the authentic integration of technology, mathematics, crosscutting concepts, science practices, and easy implementation of the Next Generation Science Standards.

TAKEAWAYS:
Use technology to expose students to coding and engineering design solutions for severe weather.

SPEAKERS:
Jessica Kohout (Independent Contractor: Ellicott City, MD), Stacy Thibodeaux (Southside High School: Youngsville, LA)

Hexagonal Thinking ensures the learning environment features a high degree of student engagement by providing a framework for academic discussion where all students participate. Participants will collaborate with colleagues to experience Hexagonal Thinking using science and math content vocabulary and visuals that will then be used to synthesize information into a piece of critical writing.

TAKEAWAYS:
Participants will learn a strategy for making thinking, learning and content connections visible in the classroom.

SPEAKERS:
Michelle Yates (Aledo ISD: Aledo, TX), Miranda Rosenhoover (Aledo ISD: Aledo, TX)

During this session, I will provide participants with black card stock, needles, string, graph paper and tape. We will start by creating the artwork as this will fuel the discussion later. I will walk participants through the steps using a guided slideshow with pictures. They will be given multiple options and allowed to experiment with their selections. I will give them time to work at their tables to create their art and walk around to help. The discussion portion will happen after the art creation. I will ask the groups to share their art with their table. The valuable portion of the session is when we will brainstorm the modifications that can be done to help all students access this activity. I will ask groups to discuss and share out as I create a list. I will add any modifications not already mentioned. Next, I would like the groups to discuss how this can be used in their classes, including the modifications they would need to suit their students. As a take away, participants will have a note taking sheet, access to the slideshow (includes examples and instructions), list of supplies needed and where to purchase, their beautiful artwork, and valuable discussions.

TAKEAWAYS:
In addition to the art work, participants will leave with ideas, templates and modifications for a variety of students.

SPEAKERS:
Terri Serey (Orange Grove Middle School: Hacienda Heights, CA)

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)

Engage in a variety of activities, collect information and resources, and network with middle level leaders. Discover new ideas and materials that you can use next week.

TAKEAWAYS:
The participants will network with other middle level science educators and leaders to discover and engage in activities that will expand their knowledge and be usable in all aspects of their work.

SPEAKERS:
Mary Lou Lipscomb (National Middle Level Science Teachers Association: Naperville, IL), Alison Seymour (Science Teacher: Winchester, 0), Carey Dieleman (National Science Teaching Association: No City, No State), Loris Chen (Science Education Consultant: Fair Lawn, NJ), Cynthia Crockett (Center for Astrophysics | Harvard & Smithsonian: Cambridge, MA), Suzanne Cunningham (Purdue University: West Lafayette, IN), Katy Garvey (The Source for Learning, Inc.: Reston, VA), Nicole Green (Animalearn: Jenkintown, PA), Joseph Michaelis (University of Illinois Chicago: Chicago, IL), Kim Nagle (Brooks Middle School: Bolingbrook, IL), Cori Nelson (Winfield School District 34: Winfield, IL), Anne Schoeffler (Seton Catholic School: Hudson, OH), Dennis Schatz (Institute for Learning Innovation: Beaverton, OR), Alison Seymour (Science Teacher: Winchester, 0), Corydon Strawser (Lake Nona Middle School: Orlando, FL), Stacy Thibodeaux (Southside High School: Youngsville, LA), Barbara Phillips-Bredlow (Northeast Nodaway School District: Ravenwood, MO), Dawn Konieczny (Brooks Middle School: Bolingbrook, IL), Erin Towns (Edward Little High School: Auburn, ME)

Learn how to better integrate local phenomena into classroom learning through the use of long-term projects and a competition.

TAKEAWAYS:
Strategies to use student-chosen local phenomena as the basis for long-term projects and participation in a national STEM competition.

SPEAKERS:
Winnie Boyle (Army Educational Outreach Program: , United States)

Explore classroom-tested benchmark assessments and scoring guides you can use to assess students’ three-dimensional learning related to middle school performance expectations.

TAKEAWAYS:
Educators will learn about a comprehensive set of free, summative benchmark 3-D assessments designed to be used in any NGSS-focused middle school classroom.

SPEAKERS:
Maia Binding (The Lawrence Hall of Science: Berkeley, CA), Wendy Jackson (The Lawrence Hall of Science: Berkeley, CA)

Problem centered instruction is a great way to engage students, integrate content, inspire learning, and naturally incorporate all three dimensions of the NRC Framework. However, true problem centered instruction requires a major shift in both teaching and learning, requiring the one thing teachers don't have: time--the last thing teachers need is another pedagogical strategy that disrupts their entire routine. Teachers will have the opportunity to voice their concerns and discuss some barriers of problem centered teaching and learning, while also addressing the benefits for both teachers and students. Considering the benefits, there are some immediate changes that teachers can use to help shift to a problem centered environment. Recalling that problem centered learning should be complex, meaningful, and open-ended, the four strategies are: 1) Make the Content Relatable, 2) Structure: Less is More, 3) Be a Resource, Not an Answer Key, and 4) Use a Problem to Introduce a Topic. Teachers will then have an opportunity to put the strategies to immediate use by picking a lesson or topic and work with others to transform it into a three-dimensional, problem centered lesson.

TAKEAWAYS:
Teachers will explore four strategies that promote three-dimensional learning through the process of problem centered instruction that is complex, meaningful, and open-ended. They will discuss benefits and barriers to the problem centered approach from the perspective of both the instructor and the learner. Teachers will have an opportunity to brainstorm and work collaboratively on transforming a lesson or topic of their choice into a problem centered, reality based scenario that seamlessly integrates the Science and Engineering Practices, Crosscutting Concepts, and Disciplinary Core Ideas.

SPEAKERS:
Cassandra Armstrong (Illinois Mathematics and Science Academy: Aurora, IL)

Learn about NASA’s Next Gen STEM educator resources and how to join our first online community of practice for STEM educators (CONNECTS).

TAKEAWAYS:
Educators will learn about future opportunities with NASA for student participation while completing a lunar lander design challenge.

SPEAKERS:
Lynn Dotson (NASA Office of STEM Engagement-GoH: Kennedy Space Center, FL)

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)

Participants will learn about the framework for computational thinking and then learn to apply it to science inquiry investigations using Block Coding (used with students in elementary and middle school in many jurisdictions) and how it can be used to improve the conduct of science investigations (and be more like the investigations conducted by scientists).   Participants will apply the computational thinking framework to creating/modifying/using simple programs (either using a free online programming tool OR with a simple, inexpensive microcontroller that will be loaned by the presenters) that can be used in science inquiry investigations either for conducting the investigation (e.g., a random number generator) or for collecting data (e.g., a counter and a timer). Investigations where these can be used will be discussed and demonstrated. The use of the microcontrollers and/or a free online programming tool to develop a simple measurement tool provides participants (and their students) an opportunity to experience a simulated situation a scientist or engineer would face as they use computing tools to develop automated measuring responses.   Finally, as an example of what is known as “physical computing”, participants will learn to build (and will build if time allows) a physical interface (to use with a computer or Chromebook) that allows them to interact with a program they have either written or downloaded.   Participants will be provided printed copies of example lesson plans and instruction sheets on how to engage students with using the Scratch program and the microcontrollers). Note that no knowledge of coding or any equipment is necessary to participate in this workshop. 

TAKEAWAYS:
Attendees will learn how computational thinking (applied to simple block coding examples and simple micro-controllers) can be used in science classrooms to help students conduct better inquiry investigations and better experience “authentic” science practices.

SPEAKERS:
G. Michael Bowen (Mount Saint Vincent University: Halifax, NS), Susan German (Hallsville Middle School: Hallsville, MO)

The free NASA STEM lesson plans introduce the practice of computational thinking and include elements of a real NASA mission. NASA’s Artemis program will return humans to the lunar surface for the first time since 1972, the year of the agency's last Apollo moon landing. This Educator Guide provides four standards-aligned activities to help students learn about NASA's Orion spacecraft that will take astronauts to the Moon and beyond. In this session, we will design and build a crew module model that will secure two 2-cm astronaut figures during a drop test. The PowerPoint will be available to all participants. The PowerPoint will include the videos and activities including the tips and pointers. Session Outline: 5 min - Welcome and Introduction to NASA Artemis Mission 10 min- STEM Engagement strategies and culturally relevant teaching 10 min- Introducing the Engineering Design Challenge 20 min- Teams Design a Crew Vehicle 10 min- Testing the Crew Vehicle 5 min- Reviewing the Resources and Q and A https://www.nasa.gov/sites/default/files/atoms/files/np-2020-02-2805-hq.pdf

TAKEAWAYS:
NASA provides free educational resources that include educator guides with standards-aligned activities to help students use computational thinking while including elements of real NASA missions.

SPEAKERS:
Susan Kohler (NASA Glenn Research Center: Cleveland, OH)

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)

This session will introduce participants to Our Beautiful Planet, a collection of classroom-ready films and lesson plans that highlight the science and engineering practices scientists use to explain the phenomenon of climate change. The collection of over 10 lessons brings Sensemaking to environmental science by cultivating student curiosity with engaging and eye-popping phenomena. Participants will generate questions and use model data as evidence to construct an explanation of how increases in global temperature could shift infection rates of mosquito-borne diseases. Using their explanation and information provided in the film, participants will consider the effect of this shift on humans.

TAKEAWAYS:
Providing students with an engaging and relevant phenomenon can be used to drive student learning about climate change and inspire them to examine critical climate issues in their own communities.

SPEAKERS:
Patrice Scinta (NSTA: Arlington, VA), Kristin Rademaker (NSTA: Arlington, VA), Holly Hereau (NSTA: Arlington, VA)