Use innovative video-assisted STEM activities, demonstrations, award-winning videos, and behind-the-crash-tests tours to teach the science of car crashes. Visit classroom.iihs.org for more information.

TAKEAWAYS:
Participants learn how to incorporate culminating STEM design challenges (Project Pedestrian Sensors and Egg-Carrying Paper Car Crash) into their curriculum to promote student awareness and understanding of how engineering and technology are used to build safer vehicles.

SPEAKERS:
Griff Jones (University of Florida: No City, No State), Pini Kalnite (Insurance Institute for Highway Safety Highway Loss Data Institute: Arlington, VA)

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)

Using data collection , participants will learn how to actively engage students in a conversation about data and the phenomena that it explains. Participants will learn how to create and/or modify old lessons, labs, and activities into opportunities for discussion , inquiry, and discovery using calculators, Nspire, and labquests.

TAKEAWAYS:
Create a dynamic lesson for use in the science classroom using data collection.

SPEAKERS:
Chris Coker (Camden Fairview High School: Camden, AR)

We are naturally curious, prone to ask why? How? What? Unfortunately, somewhere along the way students lose the trust in their voices to ask questions of and from data. But data are what we use to do science and it permeates all aspects of society today. What should we do? Stop teaching the vocabulary of science and data first, and instead leverage classroom-ready strategies to empower students to lead with their innate curiosity to practice critical 21st century data literacy skills and master the science content. Join us to explore connections between our science content, inquiry-based activities, and data skills. We will experience research-based strategies and freely available resources for integrating phenomenon-based and local data into our science instruction to promote science literacy and student empowerment. We will participate in activities ourselves and reflect on approaches for how to bring these into our classrooms. Participants will leave more empowered to integrate data into their science content in purposeful ways to better help students do and communicate science. Working with and learning science from data fosters critical thinking skills, lifelong interests in science, and facilitates learners’ overall self-identity as a scientist. Let’s set all of our students up for success!

TAKEAWAYS:
Participants will identify how data literacy is a critical aspect of science literacy in the 21st century, how students can do a lot more with data than we often think or presume from their science vocabulary alone, and how to leverage existing strategies to authentically integrate data into 6-12 science instruction to teach their science content and increase literacy simultaneously.

SPEAKERS:
Kristin Hunter-Thomson (Dataspire Education & Evaluation, Rutgers University: Princeton, NJ)

This session is intended to discuss the importance of formative assessment as a tool for guiding students and helping all students to make progress. A variety of formative assessment tools will be explored. Most importantly, the use of individual feedback on formative assessments will be demonstrated and we will discuss how this leads to improved metacognition and critical thinking skills for students. Attendees will see sample student work on formative assessments and accompanying sample teacher feedback. They will practice making comments of there own, in addition to discussing logistical concerns with the practice of individualized feedback.

TAKEAWAYS:
This session is intended to discuss the importance of formative assessment as a tool for guiding students and helping all students to make progress.

SPEAKERS:
Jennifer Maguire (Virginia Tech: Blacksburg, VA)

Science teachers at Lindblom Math and Science Academy in Chicago Public Schools have worked with Northwestern University’s CT-STEM department to develop computational thinking in science units aligned with the Next Generation Science Standards. The goal is for students to understand and apply computational thinking practices in their science classrooms to help make sense of phenomena or problems, analyze data, use models and develop explanations. Units, built by teachers, are designed to cover core science concepts in physics, chemistry, and biology. This program allows teachers to work with CT-STEM members to develop new simulations or other CT activities that work best in the unit. This was developed based on teacher need, when simulations didn’t exist to address the big ideas. Integration of NetLogo models, SageModeler, NetTango, and other data analysis activities are used to help students make real world connections. These tools allow students to learn and apply basic computer science ideas and skills as well as the 3-D of NGSS. Developed unit topics include: stoichiometry, climate change, gas laws, and energy. These units are available for public use and can be easily modified on the CT-STEM platform for teachers to use.

TAKEAWAYS:
Overview of how teachers integrated Computational Thinking into science units and how to access units for Biology, Chemistry, Physics, and Earth Science

SPEAKERS:
Carole Namowicz (Lindblom Math and Science Academy: Chicago, IL), Lauren Levites (Lindblom Math and Science Academy: Chicago, IL)

Attendees will experience the Anchoring Phenomenon Routine as students do in iHub’s Polar Ice unit. This routine engages students in asking questions about why people from around the Earth are being displaced from their homes as a starting point in a unit of study focused on how we can slow or stop polar ice from melting before the sea level rises too much. After experiencing the routine, attendees will analyze the routine through an equity lens.

TAKEAWAYS:
Attendees will learn how the iHub curriculum supports teachers in eliciting and making use of students’ own questions and their experiences in instruction, which supports student motivation and agency (Harris, Phillips, & Penuel, 2011).

SPEAKERS:
Rachel Patton (Denver Public Schools: No City, No State), Kathryn Fleegal (Denver Public Schools: Denver, CO), Beth Vinson (Denver Public Schools: Denver, CO)

Student understanding of how science and STEM ideas and concepts are applied within their chosen career pathway is a critical component of many Career and Technical Education (CTE) programs, but for a variety of reasons these connections are often overlooked. Some states even provide CTE courses and Career Pathway standards that seem to go against the three-dimensional and student-centered learning grain. Yet, to truly meet the vision of the K-12 Framework, students in CTE and Vocational Education pathways should also be provided opportunities to engage in three-dimensional sensemaking in the context of their CTE course. In this session, we explore explicit connections between three-dimensional science learning and Agricultural, Food and Natural Resources as just one example of how three-dimensional student learning and sensemaking can be incorporated into CTE. We then explore how similar strategies can be utilized in other pathways with the goal of bridging the gap between science learning and practical application for students in CTE.

TAKEAWAYS:
Attendees will learn strategies for integrating scientific sensemaking into CTE courses to support their students' mastery of the scientific concepts they will apply in those fields.

SPEAKERS:
Bridina Lemmer (Illinois Science Teaching Association: Jacksonville, IL), Chris Embry Mohr (Olympia High School: Stanford, IL)

Unpacking the 3-D NGSS while at the same time making science instruction engaging to students is a challenge faced by science teachers across the nation. With skillful use of phenomena-based instruction, science teachers engage students by converting what the teacher planned to teach into what the students want to learn. Culturally relevant, intellectually accessible and thought-provoking phenomena enable students to make engaging connections between the required curricula content and real-life scenarios and applications. Rather than recalling discrete facts, students apply new information and use transferable problem-solving skills to explain a natural or man-made phenomenon. Phenomenon-based science encourages students to ask questions, discover connections, and design models to make sense of what they observe. This session provides participating teachers opportunities to experience lessons in the same manner as students will. They examine a phenomenon and then ask questions, collaborate with partners and design models, and discuss digital tools that can be used to engage students in phenomenon-based learning. Teachers learn how to use questioning techniques and academic dialogue to spike discontent in the students' understanding of the phenomena, thereby, driving students to use science practices to further explore their curiosities

TAKEAWAYS:
Help teachers to develop and deploy thought-provoking phenomena that will promote student engagement, comprehension, and achievement in the sciences by transforming what the teacher planned to teach into what the students are eager to learn.

SPEAKERS:
Chidi Duru (Prince George's County Public Schools: Upper Marlboro, MD)

Learning through place-based, student-centered, teacher-facilitated STEM inquiry increases student engagement in and ownership of learning and promotes student growth in science and engineering practices, disciplinary core ideas, and crosscutting concepts. Using a unit plan I developed for exploring local microclimates, participants will engage in activities and discussion of techniques for cultivating students as collaborators in the learning process. The unit is designed to encourage growth in asking questions, designing and conducting investigations, collecting data, making sense of data, communicating findings, and identifying local problems and designing solutions to a student-identified problem. Participants will use NASA infrared images of surface temperatures captured during an ISS mission to observe the urban heat island phenomenon. They will explore Google Earth to spark questions about surface heating that can be answered through investigation of the local neighborhood or school campus. Given a list of equipment that students used during the unit, participants will collaboratively design an investigation to collect place-based data. Discussion includes extension activities that facilitate student understanding of surface heating and cooling. Discussion also includes how revision and reflection can be used to monitor individual student growth and promote ownership of learning by students. Emphasis is on facilitation techniques.

TAKEAWAYS:
Learning through place-based, student-centered, teacher-facilitated STEM inquiry increases student engagement in and ownership of learning and promotes student growth in science and engineering practices, disciplinary core ideas, and crosscutting concepts.

SPEAKERS:
Loris Chen (Science Education Consultant: Fair Lawn, NJ)