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1. 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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2. Nature and Extent of Science and Engineering Practices Coverage in K-12 Engineering Curriculum Materials

   CHABALENGULA, V.M. (April 2017, International journal of engineering education)

   The integration of science and engineering practices in K-12 science education is currently an area of growing national interest in the United States, as evidenced in the recently published document titled A framework for K-12 science education: Practices, crosscutting concepts, and core ideas. However, to date, little is known about the extent to which these practices are covered in the widely used K-12 engineering programs. As a response to the dearth of research in this area, this study investigated the nature and extent to which science and engineering practices are covered in the widely used K-12 engineering programs in the United States. Nine programs that are widely used in the United States were analyzed via document content analysis method using the K-12 science education framework. The results revealed important findings showing the similarities and disparities in the coverage of science and engineering practices in the analyzed programs, grade levels, and in different science discipline units. This study is significant because an understanding of the current status of science and engineering practices coverage would be helpful to educators and curriculum designers as they strive to further the development of integrated science and engineering curricula, as well as shaping the scope and sequence of engineering design thinking learning activities in the K-12 science curriculum. Key Words: engineering practices; science practices; K-12 engineering education; K-12 science curriculum 

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3. Engineering Explorations: Connecting K-12 classroom learning and field trip experiences through engineering design

   Harlow, D. (July 2021, 2021 American Society for Engineering Education Conference Proceedings)

   null (Ed.)

   Interactive science centers are in a unique position to provide opportunities for engineering education through K-12 field trip programs. However, field trip programs are often disconnected from students’ classroom learning, and many K-12 teachers lack the engineering education background to make that connection. Engineering Explorations is a 3-year project funded by the National Science Foundation (NSF) program Research in the Formation of Engineers (RFE) (EEC-1824856 and EEC-1824859). The primary goal of this project is to develop and test engineering education modules that link K-12 students’ classroom learning to field trip experiences in an interactive science museum, increasing student learning and extending the field trip experiences. Each Engineering Explorations module consists of one 50-minute field trip program completed at an interactive science center and curriculum for three 50-minute lessons to be implemented by the classroom teacher before (2 lessons) and after (1 lesson) the field trip program. Our paper will present both development and research outcomes. 

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4. Work in Progress – The Development of a K-12 Integrated STEM Observation Protocol.

   Roehrig, G.H; Ring-Whalen, E.A.; Wieselmann, J.R.; Dare, E.A.; Ellis, J.A. (January 2019, ASEE Annual Conference proceedings)

   This WIP presentation is intended to share and gather feedback on the development of an observation protocol for K-12 integrated STEM instruction, the STEM-OP. Specifically, the STEM-OP is being developed for use in K-12 science and/or engineering settings where integrated STEM instruction takes place. While the importance of integrated STEM education is established through national policy documents, there remains disagreement on models and effective approaches for integrated STEM instruction. Our broad definition of integrated STEM includes the use of two or more STEM disciplines to solve a real-world problem or design challenge that supports student development of 21st century skills. This issue is confounded by the lack of observation protocols sensitive to integrated STEM teaching and learning that can be used to inform research of the effectiveness of new models and strategies. Existing instruments most commonly used by researchers, such as the Reformed Teaching Observation Protocol (RTOP), were designed prior to the development of the Next Generation Science Standards and the integration of engineering into science standards. These instruments were also designed for use in reform-based science classrooms, not engineering or integrated STEM learning environments. While engineering-focused observation protocols do exist for K-12 classrooms, they do not evaluate beyond an engineering focus, making them limited tools to evaluate integrated STEM instruction. In order to facilitate the implementation of integrated STEM in K-12 classrooms and the development of the nascent integrated STEM education literature, our research team is developing a new integrated STEM observation protocol for use in K-12 science and engineering classrooms. This valid and reliable instrument will be designed for use in a variety of educational contexts and by different education stakeholders to increase the quality of K-12 STEM education. At the end of this project, the STEM-OP will be made available through an online platform that will include an embedded training program to facilitate its broad use. In the first year of this four-year project, we are working on the initial development of the STEM-OP through video analysis and exploratory factor analysis. We are utilizing existing classroom video from a previous project with approximately 2,000 unique classroom videos representing a variety of grade levels (4-9), science content (life, earth, and physical science), engineering design challenges, and school demographics (urban, suburban). The development of the STEM-OP is guided by published frameworks that focus on providing quality K-12 integrated STEM and engineering education, such as the Framework for Quality K-12 Engineering Education. Our anticipated results at the time the ASEE meeting will include a review of our item development process and finalized items included on the draft STEM-OP. Additionally, we anticipate being able to share findings from the exploratory factor analysis (EFA) on our video-coded data, which will identify distinct instructional dimensions responsible for integrated STEM instruction. We value the opportunity to gather feedback from the engineering education community as the integration of engineering design and practices is integral to quality integrated STEM instruction. 

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5. NGSS and the landscape of engineering in K-12 state science standards: NGSS AND THE LANDSCAPE OF ENGINEERING IN K-12

   https://doi.org/10.1002/tea.21199  

   Moore, Tamara J; Tank, Kristina M; Glancy, Aran W; Kersten, Jennifer A (March 2015, Journal of Research in Science Teaching)

   Recent documents pertaining to K-12 education have fostered a connection between engineering and science education to help better prepare our students and future citizens to better meet the current and future challenges of our modern and technological society. With that connection, there has been a concerted effort to raise the visibility of engineering within K-12 science education, which is reflected in the Framework for K-12 Science Education and the recently released Next Generation Science Standards. As states look towards the adoption and implementation of the Next Generation Science Standards, it is important to take a deeper look at the shift in K-12 science education that is being suggested by these documents and what that means in terms of the potential changes for states that have chosen to adopt these standards. The main research question that has guided the work for this paper is: What is the extent and quality of the engineering that is present in state science standards and the Next Generation Science Standards? This paper will present a detailed analysis of the landscape of engineering in K-12 policy before and after the release of the NGSS through a comparative case study of academic state science standards and Next Generation Science Standards. This comparison provides insight into what the widespread adoption of the NGSS would mean in terms of potential changes in the way we implement science education in the United States. 

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