Science literacy is essential to be informed and engaged citizens in the 21st century. Data are what we use to do science. Thus, reading and making sense of real-world data are fundamental skills to being scientifically literate and a fun way to engage learners with science. However, how do we incorporate data into K-8 science without feeling overburdened with yet another thing to teach? By integrating it into what we are already doing! Join us to explore the connections between data, science, and literacy. 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. We will participate in activities ourselves and reflect on approaches for how to bring these into our classrooms. The goal is to increase our data toolkit of strategies and resources to increase science literacy and relevance for students. Participants will leave more empowered to integrate data into their science content in purposeful ways to better helps students do and communicate science. Working with and learning from data fosters critical thinking skills, lifelong interests in science, and facilitates learners’ literacy skills. Let’s set our students up for success now and in the future!

TAKEAWAYS:
Participants will identify how data literacy is a critical aspect of science literacy in the 21st century and how to leverage existing strategies to authentically integrate data into K-8 science instruction to teach their science content and increase literacy simultaneously.

SPEAKERS:
Kristin Hunter-Thomson (Dataspire Education & Evaluation, LLC: No City, No State)

Trade books are often used to support science instruction, and are an effective way to connect ideas about how science works to classroom science experiences. In this workshop, we will share a rubric for evaluating trade books for science read-alouds and discuss how the tool can be used to inform instruction (e.g., developing discussion questions). The rubric focuses on four concepts related to humanizing science, and aligned with views of nature of science in the Next Generation Science Standards: Science is done by diverse people, Scientists interpret empirical evidence to support their claims, Scientists use a variety of methods, and Scientists are creative at all stages of their investigations. These four concepts support students’ understanding of how science works, laying the foundation for being an effective consumer of science. Additionally, these four concepts present a more accurate representation of scientists, in contrast with many long-standing stereotypes about scientists. Attendees will have the opportunity to use the rubric to analyze elementary-level science trade books and develop a plan for implementing the read-alouds in class. We will conclude by examining how teachers can layer selected trade books effectively into their existing science curriculum.

TAKEAWAYS:
Attendees will learn why representing science as a human activity is important for students’ understanding of how science works, and will learn how to select and plan for read-alouds of books that humanize science into their existing science curriculum.

SPEAKERS:
Jeanne Brunner (University of Massachusetts Amherst: Amherst, MA), Kathleen Mahoney (Doctoral Student)

By the end of this session, participants will be able to: - Explain the impact of roads on wildlife - Analyze data to design wildlife-friendly crossing structures - Use hands-on tools to teach STEM concepts The majority of this session will focus on real world data analysis and problem solving. Working in small groups, participants will propose solutions to a number of related scenarios. First, they’ll analyze data to determine if highways pose a significant threat to wildlife. Relevant vocabulary will be introduced – including fragmentation, migratory barriers, porosity and passage rates – as we explore the need for ways to move animals across highways without impacting humans. Once a need is determined, they’ll continue their exploration by looking at potential crossing structure solutions. They’ll identify structure location and wildlife-friendly designs to ensure the highest use. They’ll be asked to either create a model or blueprint of their design. Finally, participants will discuss ways to determine the crossing structure effectiveness. This will include a cost/benefit analysis. Additional resources to expand learning will be shared, including links, books, videos, contacts and professional development.

TAKEAWAYS:
Science and Engineering Practices are used by wildlife biologists to help manage wildlife populations and those same skills can be developed in students.

SPEAKERS:
Eric Proctor (Arizona Game and Fish Department: Phoenix, AZ)

How are you engaging all students in critical skills to ensure they are ready for the future of work? What does the classroom feel, sound, and look like when students are making sense of their world and solving real-world problems? Join the alumni from the 2021 Northrop Grumman Foundation Teachers Academy as they share the ways they have transformed their schools/classrooms to align with the reality of work as experienced alongside engineers, technologists, and scientists.

TAKEAWAYS:
Strategies to integrate workforce skills aligned with the vision of the K–12 Framework.

SPEAKERS:
Rachel Kenning (Spring Creek Middle School: Providence, UT), Anthony Carter (Middle River Middle School: Middle River, MD), Yevgeny Pevzner (Kearns Junior High School: Salt Lake City, UT), Leilani O'Dell (Roscomare Road Elementary School: No City, No State)

Using real-world phenomena asks students to puzzle out answers to problems that occur in their day-to-day lives. It encourages students to enter into sensemaking using their own prior knowledge and tools. One of the best tools to make sense of a phenomenon is math. Learn from CCSS Math and NGSS specialists about using mathematical thinking to promote scientific literacy. This session includes a focus on student agency, sensemaking, and supporting connections between the STEM classroom and real-world phenomena. The presenters will map CCSS Mathematics and NGSS connections while providing strategies for increasing agency and sensemaking in the classroom. Questions we will consider include: How do we support all students in becoming mathematical thinkers? How do we promote agency by providing students with authentic, engaging opportunities to collect, analyze, and interpret real-world data? How can phenomena and questioning techniques support mathematical thinking?  Come explore new possibilities of what high-quality sensemaking with math can look like for all learners.

TAKEAWAYS:
Teachers will take away strategies to integrate mathematical thinking into student sensemaking about scientific phenomena.

SPEAKERS:
Emily Mathews (NSTA: Arlington, VA), Alanna Mertens (DePaul University STEM Center: Chicago, IL)

NEED’s Science of Energy stations provide a hands-on approach to experimenting with objects used in student’s daily lives while incorporating scientific processing skills such as making observations, measuring, recording results, compare and contrast, categorize, make predictions, analyze and graph results, and draw conclusions. Workshop participants will rotate through six stations just as their students would in the classroom or OST Program, to learn about the different forms of energy and energy transformations using objects such as a toy car, apple, yo-yo, compass, bouncy ball, glow stick, etc. Using the same materials, the station guides can be easily differentiated for elementary, intermediate, and secondary levels. Each station includes a "What's Happening" article that provides additional informational text on the energy transformation that took place at the station and ties to more real-life examples for further visualization and understanding. The station guides have been correlated to each state’s individual science and math standards, as well as effectively support Next Generation Science Standards.

TAKEAWAYS:
Workshop participants will engage in hands-on experiments just as their students would, using items we encounter in our daily lives that demonstrate energy forms and their transformations and applications to real-life examples for further visualization and understanding.

SPEAKERS:
Cori Nelson (The NEED Project: Manassas, VA), Sharon Bird (The NEED Project: Manassas, VA)

Marine debris is a widespread pollution problem in our ocean and waterways. It can harm wildlife, habitats, and our economy. This issue is human-caused, but it also has human solutions. The National Oceanic and Atmospheric Administration (NOAA) Marine Debris Program is dedicated to better understanding and preventing marine debris and its impacts on our environment. One of the best tools we have to combat marine debris is understanding the distribution, abundance, and types of debris in the marine environment. The Marine Debris Monitoring & Assessment Project (MDMAP) is a NOAA citizen science initiative to survey and record marine debris on shorelines. By participating in the MDMAP, students can generate critical data on marine debris for use by community organizations, policymakers, researchers, and NOAA. MDMAP data can also support student-generated action projects, providing opportunities to plan and implement authentic changemaking efforts. The NOAA Marine Debris Program plans to demonstrate and solicit feedback on an updated tool to support implementation of the MDMAP protocols with students: The MDMAP Educators’ Guide (Guide). We will introduce the updated protocols, provide a demonstration of activities in the Guide, and engage in a discussion with educators about implementation, suggested extensions (including action projects), and feedback.

TAKEAWAYS:
Attendees at this session will learn about the updated Marine Debris Monitoring & Assessment Project Educators’ Guide: a refreshed citizen science tool for monitoring shoreline marine debris available from the NOAA Marine Debris Program, including planning and conducting protocols with students, working with survey data, and creating authentic, meaningful action projects for students based on their experiences.

SPEAKERS:
Alexandria Brake (NOAA Office of Education: Silver Spring, MD), Tanya Kea-Marie Torres (California Sea Grant Marine Debris Extension Fellow: , CA)

Students come into a science classroom with varying or little to no background knowledge. Mathematical modeling in the science classroom is a critical piece of any three-dimensional lesson. Come learn how one science teacher uses real-world student-collected data to make modeling fun and inclusive of all students!

TAKEAWAYS:
Equity in the science/math classroom; data collection and analysis; and mathematical modeling.

SPEAKERS:
Stacy Thibodeaux (Southside High School: Youngsville, LA)

In this session, the participants will explore some lessons developed by teachers in the National Space Biomedical Research Institute-Teacher Academy Project (NSBRI-TAP). These are interactive, physical and focus on spatial disorientation and the musculoskeletal system as affected by microgravity. The teachers will engage in the activities and collect sample data as they would with students and interpret the results. These are both educational and fun as we need to desperately restore enthusiasm for science studies. The presenter has anecdotal stories from many astronauts of their physiological reaction to microgravity conditions that he will share. Teachers will be provided lesson plans and worksheets for use with their students. Sample activities: Title: IN-FLIGHT EXERCISES Grade Level: 5-8 Content Area: Life Science and Health National Science Content Standards: Standard A. Science as Inquiry (Grades 5-8 & 9-12) • Abilities necessary to do scientific inquiry • Understandings about scientific inquiry Standard C. Life Science (Grades 5-8) • Structure and function in living systems • Regulation and behavior Standard F. Science in Personal and Social Perspectives (Grades 5-8 & 9-12) • Personal health Title: SHIFTY EYES Grade Level: 5-8 Content Area: Space/Life Science National Science Content Standards: Unifying Concepts and Processes (Grades 5-8) Models Standard C. Life Science (Grades 5-8) Structure and function in living systems Regulation and behavior Diversity and adaptations of organisms Dr. Wilson also participated in two experiments on NASA’s KC-135 (Vomit Comet): 1) testing a resistance exercise machine to fly in space designed at The Cleveland Clinic and 2) an experiment where the corn earworm (Helicoverpa zea) was subjected to microgravity while a control group of worms was grown by elementary students in Las Cruces, NM. He will explain and share the results of these experiments and of one flown by teachers from Miami-Dade School District in Florida involved in his Future Scientists Program.

TAKEAWAYS:
The International Space Station (ISS) is a research platform and is helping scientists develop countermeasures to the adverse effects of long-duration spaceflight on the human body.

SPEAKERS:
Craig Wilson (Texas A&M University: College Station, TX)

Complete a distracted driving simulation and discover free award-winning videos, STEM activities, and real-world applications exploring science, engineering, and vehicle crashworthiness. Free lesson plans included.

TAKEAWAYS:
Participants will learn how scientific and engineering principles can be modeled in classrooms using crash science–related videos and activities to promote safer personal behaviors when riding in or driving a vehicle.

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

Unfortunately, the Las Vegas slogan “What Happens Here Stays Here” applies all too well to science classrooms. Science learning that takes place in the classroom often stays in the classroom and fails to transform students’ perceiving and experiencing of the world. This gap between school learning and everyday experience is one of the key barriers to developing active scientific literacy. This workshop on the Teaching for Transformative Experiences in Science (TTES) model will help teachers address this problem by enacting transformative teaching. The TTES model is a research-based pedagogy for fostering transformative experiences; that is, experiences in which students use science content to enrich and expand their everyday lives. The workshop will train teachers in the application of three core design principles: (a) artistic selection and crafting of content, (b) experiential apprenticeship, and (c) doing and undergoing. The workshop will be conducted by one of the pioneers and lead researchers of transformative experience theory. It will include authentic classroom vignettes illustrating the design principles in action, application templates and guidelines, and exercises that will help participants master the design principles. The workshop is appropriate for science educators at all levels as the design principles are adaptable to all ages.

TAKEAWAYS:
Workshop participants will receive hands-on training in research-based strategies effective at fostering transformative experiences; that is, experiences in which students use their in-school learning to enrich and expand their everyday, out-of-school lives.

SPEAKERS:
Kevin Pugh (University of Northern Colorado: Greeley, CO)

The GISP2 H-Core was collected in 1992 adjacent to the Greenland Ice Sheet Project Two (GISP2) drill site. The GISP2-H 125.6-meter firm and ice core is a record of 430 years of liquid electrical conductivity and nitrate concentrations. The liquid electrical conductivity sequence contains signals from a number of known volcanic eruptions that provide a dating system at specific locations along the core. The terrestrial and solar background nitrate records show seasonal and annual variations – as well as unique events. Several major nitrate anomalies within the record do not correspond to any known terrestrial or solar events, and there is compelling evidence that some nitrate anomalies within the GISP2 H-Core could possibly be a record of supernova events. This investigation provides participants with a better understanding of the scientific process of analyzing data and developing models to construct knowledge, and defending the results. Sometimes there is no answer key, only possible solutions from analyzing and constructing knowledge from multiple sources that cross traditional disciplines. The materials focus on NGSS scientific practices, crosscutting concepts and the Earth and space sciences core disciplinary ideas – including analyzing and interpreting data, patterns, cycles of energy and matter, Earth systems and Earth and human activity.

TAKEAWAYS:
In constructing new knowledge, sometimes there is no definitive answer, only plausible conclusions based on constructing, analyzing, and comparing data and research from multiple disciplines.

SPEAKERS:
Donna Young (NASA/NSO/UoL Program Manager: Laughlin, NV)