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1. Integrating Professional Mentorship with a 3D-Printing Curriculum to Help Rural Youth Forge STEM Career Connections.

   Bhaduri, S. (July 2021, 2021 ASEE Virtual Annual Conference.)

   Economically disadvantaged youth residing in mountain tourist communities represent an important and understudied rural population. These communities typically include a large percentage of children that are English language learners. Our NSF STEM Career Connections project, A Model for Preparing Economically-Disadvantaged Rural Youth for the Future STEM Workplace, investigates strategies that help middle school youth in these communities to envision a broader range of workforce opportunities, especially in STEM and computing careers. This poster highlights the initial findings of an innovative model that involves working with local schools and community partners to support the integration of local career contexts, engineering phenomena, 3D printing technologies, career connections, and mentorship into formal educational experiences to motivate and prepare rural youth for future STEM careers. We focus on select classrooms at two middle schools and describe the implementation of a novel 3D printing curriculum during the 2020-2021 school-year. Two STEM teachers implemented the five-week curriculum with approximately 300 students per quarter. To create a rich inquiry-driven learning environment, the curriculum uses an instructional design approach called storylining. This approach is intended to promote coherence, relevance, and meaning from the students’ perspectives by using students’ questions to drive investigations and lessons. Students worked towards answering the question: “How can we support animals with physical disabilities so they can perform daily activities independently?” Students engaged in the engineering design process by defining, developing, and optimizing solutions to develop and print prosthetic limbs for animals with disabilities using 3D modeling, a unique augmented reality application, and 3D printing. In order to embed connections to STEM careers and career pathways, some students received mentorship and guidance from local STEM professionals who work in related fields. This poster will describe the curriculum and its implementation across two quarters at two middle schools in the US rural mountain west, as well as the impact on students’ interest in STEM and computing careers. During the first quarter students engaged in the 3D printing curriculum, but did not have access to the STEM career and career pathway connections mentorship piece. During the second quarter, the project established a partnership with a local STEM business -- a medical research institute that utilizes 3D printing and scanning for creating human surgical devices and procedures -- to provide mentorship to the students. Volunteers from this institute served as ongoing mentors for the students in each classroom during the second quarter. The STEM mentors guided students through the process of designing, testing, and optimizing their 3D models and 3D printed prosthetics, providing insights into how students’ learning directly applies to the medical industry. Different forms of student data such as cognitive interviews and pre/post STEM interest and spatial thinking surveys were collected and analyzed to understand the benefits of the career connections mentorship component. Preliminary findings suggest the relationship between local STEM businesses and students is important to motivate youth from rural areas to see themselves being successful in STEM careers and helping them to realize the benefits of engaging with emerging engineering technologies. 

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2. Computational Thinking Integration into Middle Grades Science Classrooms: Strategies for Meeting the Challenges

   Boulden, D.C.; Wiebe, E.; Akram, B.; Aksit, O.; Buffum, P.S.; Mott, B.; Boyer, K.E.; Lester, J. (January 2018, Middle grades review)

   This paper reports findings from the efforts of a university-based research team as they worked with middle school educators within formal school structures to infuse computer science principles and computational thinking practices. Despite the need to integrate these skills within regular classroom practices to allow all students the opportunity to learn these essential 21st Century skills, prior practice has been to offer these learning experiences outside of mainstream curricula where only a subset of students has access. We have sought to leverage elements of the research-practice partnership framework to achieve our project objectives of integrating computer science and computational thinking within middle science classrooms. Utilizing a qualitative approach to inquiry, we present narratives from three case schools, report on themes across work sites, and share recommendations to guide other practitioners and researchers who are looking to engage in technology-related initiatives to impact the lives of middle grades students. 

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3. STEAM learning in an in-school makerspace: The role of distributed spatial sensemaking.

   Ramey, K. E.; Stevens, R.; Uttal, D. H. (January 2018, Proceedings of the 13th International Conference of the Learning Sciences, London, UK)

   This study examines technology-enhanced STEAM learning among fifth and sixth grade students in one set of in-school makerspaces. It focuses on the learning of one set of meta-disciplinary skills, spatial skills. Prior research has shown these skills to be relevant for STEAM achievement, but they have been underemphasized in our schools and in the literature on learning through making. Informed by a distributed cognition perspective and using a combination of qualitative categorical coding and interaction analysis, this study provides a learning sciences approach to studying spatial thinking and learning. Analyses show that during making activities students engaged in frequent and diverse spatial thinking with a variety of social and material resources and that the sociomaterial contexts of different making activities facilitated different types of spatial thinking. They also show that spatial thinking developed over time and led to problem-solving insights. 

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4. Studying the Interactions Between Science, Engineering, and Computational Thinking in a Learning-by-Modeling Environment.

   https://doi.org/10.1007/978-3-030-52237-7_48  

   Zhang, N.; Biswas, G.; McElhaney, K.; Basu, S.; McBride, E.; Chiu, J. (June 2020, In: Bittencourt I., Cukurova M., Muldner K., Luckin R., Millán E. (eds) Artificial Intelligence in Education. AIED 2020. Lecture Notes in Computer Science.)

   Computational Thinking (CT) can play a central role in fostering students' integrated learning of science and engineering. We adopt this framework to design and develop the Water Runoff Challenge (WRC) curriculum for lower middle school students in the USA. This paper presents (1) the WRC curriculum implemented in an integrated computational modeling and engineering design environment and (2) formative and summative assessments used to evaluate learner’s science, engineering, and CT skills as they progress through the curriculum. We derived a series of performance measures associated with student learning from system log data and the assessments. By applying Path Analysis we found significant relations between measures of science, engineering, and CT learning, indicating that they are mutually supportive of learning across these disciplines. 

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5. 3D plants: Deploying Emerging Technologies to Revolutionize STEAM+Ag Education

   Arango-Caro, Sandra; Langewisch, Tiffany; Ying, Kaitlyn; Arellano_Haberberger, Michelle; Ly, Nate; Branton, Christopher; Callis-Duehl, Kristine (May 2024, National Science Foundation)

   This project addresses the disconnect between science, design, and technology and how high school students can benefit from innovative learning experiences in plant science that integrate these disciplines while gaining interest in and skills for future STEM careers. We created a project-based 3D modeling learning module with educators as facilitators and students working in collaborative teams of self-identified science, technophile, and art students. Students created 3D models of plants under research at the Donald Danforth Plant Science Center and learned about the applications of 3D modeling in augmented and virtual reality platforms. They also disseminated their project results through handouts and presentations. We used a mixed-methods approach to assess the impact of implementing this module on students’ learning and interests in STEAM subjects and careers. We found that students are more aware of the intersection of art and design with science and gained literacy in plant science, design, and technology. The students also gained 21st century skills such as collaboration, communication, creative thinking, and problem-solving and showed more interest in STEAM subjects and careers. This project contributes to the body of knowledge on theory, best practices, and practical technological applications in STEAM education. 

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