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)

To effectively engage audience members, I will balance their readiness to learn, cognitive load, and stimulating activities. Using real-world examples, I will demonstrate the power of STEM in elementary classrooms to grow all learners and provide necessary 21st-century skills. Often STEM is an enrichment offered to high-achiever but struggling learners have even more to gain from STEM including confidence and leadership. I will focus on practical application, but valuable references and data will be included to support my practices. I will begin the session with a survey to identify the needs and perceptions of participants regarding STEM integration. Based on input, I will share research-based strategies, classroom integration examples, or dispel misconceptions. I will include an interactive STEM activity using index cards and paper clips to provide a STEM lesson model and demonstrate the ease of integrating STEM with simple, classroom supplies. Participants will leave the session with a better understanding of the benefits of STEM in K-5 classrooms and feel more comfortable integrating STEM into their own classrooms.

TAKEAWAYS:
Participants will understand the value of STEM integration beyond the four letters of the acronym, including the benefits of productive struggle of high achievers and how the grit of struggling learners are paramount in the success of STEM challenges.

SPEAKERS:
Erika Neuman (University of Texas at San Antonio: No City, No State)

Participants will use sensemaking and the engineering design process to solve a real world food production problem in a small scale format. This lesson introduces the Food Delivery Challenge, in which participants must design a gravity feeder to carry food (chicken feed) to twelve hungry chickens for over 24 hours. To accomplish the task students must design and build a model of an efficient gravity feeder using the materials available to them. The scenario presented to the class: One of the feeders in your uncle’s barn has broken down, and a new one will not arrive until next month. You must create a gravity feeder to satisfy 12 chickens for 24 hours consistently to ensure the health of your flock. Participants will research, design, build and test their design before presenting to the group for feedback, Participants will then use the feedback to redesign for an improved feeder.

TAKEAWAYS:
1. Use the engineering design process to collaborate, design and build a gravitational feeder system that will feed 10 pounds of feed over a 24 hour period. 2. Present your design plan, and final product to the class for feedback. 3. Provide feedback to the design team for design improvement.

SPEAKERS:
Leah LaCrosse (McCormick Junior High School: Huron, OH), Heather Bryan (Nourish the Future - Education Projects, LLC: Columbus, OH)

In this hands-on workshop, participants will make and preform tests on COVID masks to use engineering practices to design a mask that is both comfortable and protective.

TAKEAWAYS:
Inquiry-based STEM is a collaborative process in which students act and think like engineers and scientists to make the learning environment inclusive for ALL learners.

SPEAKERS:
Karen Ostlund (The University of Texas at Austin: Austin, TX)

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)

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)

Students utilize different components (enzymes, yeast, feed stocks, and water) to produce ethanol and carbon dioxide through the process of fermentation. Students will develop a model of fermentation and explain how ethanol is made to answer the focus question "How can fermentation produce a renewable fuel source?" Students will develop experimental models to generate data in order to construct explanations about the relationships between the components of the fermentation process and to predict how those relationships can be manipulated to produce carbon dioxide. Students will design solutions to make the fermentation process as efficient as possible and generate the maximum amount of ethanol in a small bag environment Attendees will participate in hands-on activities centered around biofuel. Participants are going to prepare and compare different amounts of fermentation occurring in four different mixtures which will allow observations of production rates. A second activity focuses on a way to make a qualitative or quantitative explanation regarding the relationship between feed stock and glucose availability for ethanol production. Participants will deconstruct a model of starch to examine enzyme and starch reactions to determine how starches change into smaller molecules. Three additional hands-on activities that can be included in your classroom curriculum will be discussed.

TAKEAWAYS:
Nourish the Future is a national education initiative developed by science teachers for science teachers to connect students to modern agriculture and provide sound science based resources that meet teacher and student needs in the classroom.

SPEAKERS:
Tiska Rodgers (Hayti High School: Hayti, MO), Leanne Thele (Perryville High School: No City, No State)

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)