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1. Usable STEM: Student Outcomes in Science and Engineering Associated with the Iterative Science and Engineering Instructional Model

   https://doi.org/10.3390/educsci14111255  

   Songer, Nancy B; Calabrese, Julia E; Cordner, Holly; Aina, Daniel (November 2024, Education Sciences)

   While our world consistently presents complicated, interdisciplinary problems with STEM foundations, most pre-university curricula do not encourage drawing on multidisciplinary knowledge in the sciences and engineering to create solutions. We developed an instructional approach, Iterative Science and Engineering (ISE), that cycles through scientific investigation and engineering design and culminates in constructing a solution to a local environmental challenge. Next, we created, revised, and evaluated a six-week ISE curricular program, Invasive Insects, culminating in 6th–9th-grade students building traps to mitigate local invasive insect populations. Over three Design-Based Research (DBR) cycles, we gathered and analyzed identical pre and post-test data from 554 adolescents to address the research question: what three-dimensional (3D) science and engineering knowledge do adolescents demonstrate over three DBR cycles associated with a curricular program following the Iterative Science and Engineering instructional approach? Results document students’ significant statistical improvements, with differential outcomes in different cycles. For example, most students demonstrated significant learning of 3D science and engineering argument construction in all cycles—still, students only significantly improved engineering design when they performed guided reflection on their designs and physically built a second trap. Our results suggest that the development, refinement, and empirical evaluation of an ISE curricular program led to students’ design, building, evaluation, and sharing of their learning of mitigating local invasive insect populations. To address complex, interdisciplinary challenges, we must provide opportunities for fluid and iterative STEM learning through scientific investigation and engineering design cycles. 

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2. Usable STEM knowledge for tomorrow's STEM problems

   https://doi.org/10.56367/OAG-037-10193  

   Butler Songer, Nancy (January 2023, Open Access Government)

   Usable STEM knowledge for tomorrow's STEM problems More universities and education programs need more STEM knowledge in formal and informal settings to guide learners in applying STEM learning to the creation of solutions. To address this challenge, Nancy Butler Songer, the dean of the College of Education at the University of Utah designed a learning approach, Solutioning, that guides youth to deepen science content through science and engineering practices. Creating a six-week curricular program, the learning approach provided opportunities for students to use engineering design to create and provide feedback on a trap design that would attract a local invasive insect that was harmful to their community. Research was conducted on studies to provide empirical evidence on student STEM knowledge and learning and their ability to define science and engineering. Research results indicate that even elementary-age students demonstrate significant improvement in their understanding of STEM arguments as evaluated with a pre-post assessment before and after implementing a six-week solutioning curricular program. 

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3. The Design of a Course to Train STEM Pre-Service Teachers (Work-in-progress)

   Crosby, Garh V; Alaqra, Maram H; Simmons-Brooks, Pamela; Krauss, Morgan; Tornquist, Shelly; Yalvac, Bugrahan (June 2024, ASEE)

   In pre-college levels, integrated science, technology, engineering, and mathematics (STEM) are often taught by science or mathematics teachers. These teachers lack the engineering and technology background and they do not necessarily use project-based and inquiry-oriented instructional strategies. To close the gap in the qualified STEM education teacher workforce, the authors developed and piloted a novel course to train preservice STEM teachers to effectively employ project-based and inquiry-oriented teaching strategies at pre-college levels. This 3-credit research and design experience course was piloted in the Spring 2023 semester. The preservice STEM teachers, enrolled in the course, engaged in hands-on activities, engineering project-based training, inquiry-based learning techniques through research training, makerspace training, field experience, and mentorship. The course comprised two parts. In part I, the students received research training. In part II, the students engaged in engineering design and makerspace professional development. In this paper, we report on the course design elements and the impact of the course activities on students’ self-efficacy in teaching STEM subjects using emerging technology, as well as their teaching approaches and understanding of student learning. The authors conducted a mixed methods study and collected both qualitative and quantitative data. Preliminary results of the multiyear study are presented. Initial findings indicate a heightened confidence of the students in their ability to deliver STEM content in secondary classrooms. Students improved their teaching approaches and reported positive experiences with the course. 

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4. Why is engineering design important for all leaners?

   https://doi.org/10.56367/OAG-038-10193  

   Butler Songer, Nancy (January 2023, Open Access Government)

   Why is engineering design important for all leaners? Engineering design systematically identifies needs, wants, and problems and then devises solutions to address them. A central component of our work is guiding students in the engineered design of solutions to local environmental problems. Science in society and schools must be for all citizens. Reasons include the desire to prepare citizens with the tools and knowledge to address local and global problems. With funding from the U.S. National Science Foundation, we foster sustained learning of Science, Technology, Engineering, and Mathematics (STEM) for students from primary school through university. 

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5. Promoting Computational Thinking Through Science-Engineering Integration Using Computational Modeling

   Basu, Satabdi; McElhaney, Kevin W.; Rachmatullah, Arif; Hutchins, Nicole; Biswas, Gautam; Chiu, Jennie (January 2022, Proceedings of the 16th International Conference of the Learning Sciences (ICLS))

   Careers in science, technology, engineering, and mathematics (STEM) increasingly rely on computational thinking (CT) to explore scientific processes and apply scientific knowledge to the solution of real-world problems. Integrating CT with science and engineering also helps broaden participation in computing for students who otherwise would not have access to CT learning. Using a set of emergent design guidelines for scaffolding integrated STEM and CT curricular experiences, we designed the Water Runoff Challenge (WRC) - a three-week unit that integrates Earth science, engineering, and CT. We implemented the WRC with 99 sixth grade students and analyzed students’ learning artifacts and pre/post assessments to characterize students’ learning process in the WRC. We use a vignette to illustrate how anchoring CT tasks to STEM contexts supported CT learning for a student with low prior CT proficiency. 

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