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1. Applied Education Programming: Four Exemplars in Environmental Literacy and Teacher Professional Development

   https://doi.org/10.5670/oceanog.2024.204  

   Bruno, Barbara; Cackowski, Celia; Frederick, John; Vincent, Robert; Bennett, Andrew; Böttjer-Wilson, Daniela; Engels, Jennifer; Flight, Chris; Lang, Amy; Lawrence, Lisa; et al (January 2024, Oceanography)

   This paper shares four Sea Grant-funded projects from across the United States. The Hawai‘i project integrates Western science and Hawaiian culture in place- and community-based teaching. The Maryland program takes a project-based learning approach to aquaculture education in the formal education system. The Massachusetts (MIT) project focuses on state-of-the-art technology in engineering, robotics, and ocean science. The Virginia project emphasizes science communication and lesson plan design. What all four projects have in common is their focus on environmental literacy and teacher professional development in formal education. This approach aims to raise the quality of STEM instruction by expanding teachers’ knowledge, skills, and resources. Training teachers also efficiently utilizes resources by maximizing the number of students we ultimately reach, thereby creating sustainability. 

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2. Partnering to Develop a Coordinated Engineering Education Program Across Schools, Museum Field Trips, and Afterschool Programs

   Harlow, D. (January 2020, Connected science learning)

   Engineering Explorations are curriculum modules that engage children across contexts in learning about science and engineering. We used them to leverage multiple education sectors (K–12 schools, museums, higher education, and afterschool programs) across a community to provide engineering learning experiences for youth, while increasing local teachers’ capacity to deliver high-quality engineering learning opportunities that align with school standards. Focusing on multiple partners that serve youth in the same community provides opportunities for long-term collaborations and programs developed in response to local needs. In a significant shift from earlier sets of standards, the Next Generation Science Standards include engineering design, with the goal of providing students with a foundation “to better engage in and aspire to solve the major societal and environmental challenges they will face in decades ahead” (NGSS Lead States 2013, Appendix I). Including engineering in K–12 standards is a positive step forward in introducing students to engineering; however, K–12 teachers are not prepared to facilitate high-quality engineering activities. Research has consistently shown that elementary teachers are not confident in teaching science, especially physical science, and generally have little knowledge of engineering (Trygstad 2013). K–12 teachers, therefore, will need support. Our goal was to create a program that took advantage of the varied resources across a STEM (science, technology, engineering, and math) education ecosystem to support engineering instruction for youth across multiple contexts, while building the capacity of educators and meeting the needs of each organization. Specifically, we developed mutually reinforcing classroom and field trip activities to improve student learning and a curriculum to improve teacher learning. This challenging task required expertise in school-based standards, engineering education, informal education, teacher professional development, and classroom and museum contexts. 

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3. Implementing Computer Science in Elementary Science Classrooms: An Elementary Teacher’s Perceptions Over Four Years

   https://doi.org/10.22318/icls2025.179703  

   Lilly, Sarah; Bredder, Eric; McAlister, Anne M; Chiu, Jennifer L (June 2025, International Society of the Learning Sciences)

   As computer science (CS) is integrated in elementary science curricula, it is important to consider teachers’ perceptions in how they access CS and support students to engage in CS skills and standards through NGSS-aligned activities. This single case study utilizes the Interconnected Model of Professional Growth (IMPG) to examine teacher change and explore the perspectives of a teacher, through semi-structured interviews, as he implements an NGSS-aligned, project-based CS unit over the course of four years. Findings indicate that the teacher perceived that changes in his practice helped inform changes in student outcomes and the curriculum and, in turn, these changes in outcomes further informed his teaching practice in the next iteration of the unit. Results highlight the importance of reflection and feedback as a way to impact the teaching practice of integrating CS in elementary science education. 

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4. Implementing Computer Science in Elementary Science Classrooms: An Elementary Teacher’s Perceptions Over Four Years

   Lilly, Sarah; Bredder, Eric; McAlister, Anne M; Chiu, Jennifer L (June 2025, Proceedings of the 19th International Conference of the Learning Sciences – ICLS 2025)

   Rajala, A; Cortez, A; Hofmann, R; Jornet, A; Lotz-Sisitka, J; Markauskaite, L (Ed.)

   As computer science (CS) is integrated in elementary science curricula, it is important to consider teachers’ perceptions in how they access CS and support students to engage in CS skills and standards through NGSS-aligned activities. This single case study utilizes the Interconnected Model of Professional Growth (IMPG) to examine teacher change and explore the perspectives of a teacher, through semi-structured interviews, as he implements an NGSS-aligned, project-based CS unit over the course of four years. Findings indicate that the teacher perceived that changes in his practice helped inform changes in student outcomes and the curriculum and, in turn, these changes in outcomes further informed his teaching practice in the next iteration of the unit. Results highlight the importance of reflection and feedback as a way to impact the teaching practice of integrating CS in elementary science education. 

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5. Integrating computational thinking into middle school science through co-designed storylines

   Biddy, Q.; Gendreau Chakarov, A.; Jacobs, J.; Recker, M.; Sumner, T.; Penuel, W. (January 2020, Association for Science Teacher Education)

   We describe a professional development model that supports teachers to integrate computational thinking (CT) and computer science principles into middle school science and STEM classes. The model includes the collaborative design (co-design) (Voogt et al., 2015) of storylines or curricular units aligned with the Next Generation Science Standards (NGSS Lead States, 2013) that utilize programmable sensors such as those contained on the micro:bit. Teachers spend several workshops co-designing CT-integrated storylines and preparing to implement them with their own students. As part of this process, teachers develop or modify curricular materials to ensure a focus on coherent, student driven instruction through the investigation of scientific phenomena that are relevant to the students and utilize sensor technology. Teachers implement the storylines and meet to collaboratively reflect on their instructional practices as well as their students’ learning. Throughout this cyclical, multi-year process, teachers develop expertise in CT-integrated science instruction as they plan for and use instructional practices that align with three dimension science teaching and foreground computational thinking. Throughout the professional learning process, teachers alternate between wearing their “student hats” and their “teacher hats”, in order to maintain both a student and teacher perspective as they co-design and reflect on their implementation of CT-integrated units. This paper illustrates two teachers’ experiences of the professional development process over a two-year period, including their learning, planning, implementation, and reflection on two co-designed units. 

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