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1. Engineering Design in Scientific Inquiry

   Atkins Elliott, Leslie (January 2019, American Society of Engineering Education)

   The Engineering Design in Scientific Inquiry (EDISIn) Project addresses the engineering preparation of secondary science teachers by embedding engineering design into a science course for single-subject STEM education majors (future secondary teachers), and developing a sequence of lesson plans and annotated video for faculty who seek to embed engineering design in their science courses. While undergraduate laboratories are rich with designed experimental apparatus, it is rare that students themselves play a role in designing and producing artifacts in the service of scientific inquiry. Our expectation is that (1) existing science courses offer opportunities for students to engage meaningfully with engineering practices, by solving design challenges that emerge in the construction of scientific ideas; and (2) doing so can capitalize on existing curricula that science education has developed, facilitating the adoption of engineering design into preservice teacher education. As part of NSF’s Improving Undergraduate STEM Education (IUSE) funding program, this proposal is part of a broader effort to transform undergraduate science education, preparing students to be innovators and leaders in STEM. 

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2. Integration of Authentic STEM Practices in Real-World Education and Research Environments: Lessons from the PDP

   https://doi.org/10.58021/S5F59Q  

   West, Colin G; Honig, Susanna E; Lui, Lauren M; Raschke, Lynne (January 2022, Institute for Scientist & Engineer Educators (ISEE))

   Seagroves, Scott; Barnes, Austin; Metevier, Anne; Porter, Jason; Hunter, Lisa (Ed.)

   A significant focus of the ISEE Professional Development Program (PDP) is identifying authentic STEM practices, so that educators and scientists can develop and assess these practices as intentionally as they would scientific content knowledge. In addition to the classic inquiry-based learning activities, PDP alumni also find themselves using and teaching these STEM practices in other contexts. Many PDP participants have benefited from recognizing "STEM practices" as its own category of specific skills and knowledge, allowing them to build these practices into their work intentionally, rather than simply expecting these skills to develop naturally as a by-product of learning STEM content. We present four instances where PDP lessons have been put to work by alumni of the program in this manner, either in teaching and mentoring students, performing real-world scientific research, or both. First, we consider two instances of alumni using their PDP training to inform the way they build authentic STEM practices into college classrooms and college mentorship, at the College of St. Scholastica and at UC Santa Cruz. Next, we describe a course-based undergraduate research experience (CURE) in which students learn and employ authentic STEM research practices at the University of Colorado at Boulder. Finally, we present an example of an alumna who has used her identification of widely-applicable STEM practices to broaden her own research horizons at Lawrence Berkeley National Laboratory. 

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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. Authentic Scientific Research through an Undergraduate Ecology Course

   https://doi.org/10.1525/abt.2023.85.6.336  

   Burgin, Stephen R.; Siepielski, Adam M. (August 2023, The American Biology Teacher)

   Undergraduate science students who volunteer within a research laboratory group, or participate in funded research opportunities, in general are those who have the opportunity to engage in authentic research. In this article, we report the findings from two different iterations of a semester-long collaboration between a biology faculty member and a science education faculty member at a major research institution in the Southeastern United States. Specifically, the faculty members designed an ecology laboratory course for upper-level undergraduate students (primarily biology majors) where they would engage in an original and highly authentic ecological research project. The goal of this course was to have students explicitly learn about the nature of science (NOS), and authentic scientific practices such as inquiry and experimentation in the context of their own research. In the second year of the course, the global COVID-19 pandemic forced us to modify our approach to accomplish the same goals, but now in a remote and online format. Using questionnaires, concept inventories, and semi-structured interviews, the impact of the course on students’ understandings of NOS, inquiry, and experimentation, in addition to their perspectives on the experience within the course compared to prior laboratory coursework, was investigated. We found that students showed modest gains in each of the aforementioned desirable outcomes. These gains were generally comparable in both face-to-face and remote course settings. Additionally, students shared with us their preference for authentic laboratory work as compared with the typical laboratory work with its given research question and step-by-step instructions. Our research demonstrates what is possible in both face-to-face and remote undergraduate laboratory courses in biology and the positive impact that was observed in our students. We hope it serves as a model for other scientists and science educators as they collaborate to design authentic research-based coursework for undergraduate biology students. 

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5. Using Tinkercad in Middle School Mathematics and Science Classrooms.

   Kurz, TL; Jayasuriya, S; Swisher, K; Mativo, J; Pidaparti, R; Robinson, DT (March 2025, Association for the Advancement of Computing in Education (AACE))

   Interdisciplinary STEM education is a pedagogical approach that allows students to understand the interconnectedness of the disciplines of STEM. The interdisciplinary approach introduces problem-based learning, cooperative learning, expands problem-solving skills, and introduces students to the use of engineering design. Tinkercad is a visual computing tool that models mathematical and scientific concepts and support interdisciplinary STEM learning and experiences. In this session, participants will explore Tinkercad in the context of middle school curriculum. Free, accessible lessons that highlight the use of Tinkercad in the middle school classroom will be shared from our project. Participants will explore the gravity feature and ways to use this feature to explore mathematical and scientific concepts. 

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