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1. Development of a Middle School Architectural Engineering Pilot Program (Work in Progress)

   Wang, T ; Yong, L ; Hanagan, L ; Godwin, A ( January 2022 , ASEE 2022: American Society for Engineering Education Annual Conference & Exposition. Minneapolis, MN)

   This Work in Progress (WIP) paper describes the development of a middle school program focused on an integrated STEM architectural engineering design project and exploration of career pathways. The current engineering workforce is increasingly aging, needing new engineering graduates to meet the industry demands. It is crucial to create inclusive educational programs in STEM to expose and connect with youths from diverse backgrounds, especially the demographics that are underrepresented, in STEM career paths. Middle school is a pivotal time for generating students’ awareness of and promoting pathways into STEM careers; however, opportunities to engage in engineering are often lacking or nonexistent, particularly for low-income students. Additionally, low-income students may bring particular experiences and skills from their backgrounds to engineering that may increase the innovation of engineering solutions. These assets are important to recognize and cultivate in young students. The Middle School Architectural Engineering Pilot Program (MSAEPP), drawing from social cognitive career theory and identity-based motivation, is an intervention designed to affect STEM related content and STEM identities, motivation, and career goals for low-income students using relatable topics within the building industry. The focus on architectural engineering activities is because buildings, and the industry they represent, touch everyone’s lives. The MSAEPP is planned to be implemented through the Talent Search Programs at middle schools in Pennsylvania. The Talent Search Program is one of the Federal TRIO Programs dedicated to assisting high school students in furthering their education. Penn State Talent Search Programs serve 22 schools in 8 impoverished school districts. The pilot program engages middle school students (seventh and eighth grade) in architectural engineering related lessons and activities, by exploring engineering identities interactions with architectural engineering industry professionals, and by planning potential career pathways in architectural engineering and other STEM careers with Talent Search Counselors. The purpose of this paper is to present the background and process used in this funded NSF project for developing the suite of architectural engineering related lessons and activities and the research plan for answering the research question: How does the combination of meaningful engineering learning, exposure to professional engineers, and career planning, focused on building industry engineering applications, increase identity-based motivation of students from low-income households and marginalized students in pursuing STEM careers? Answering this question will inform future work developing interventions that target similar goals and will validate and expand the identity-based motivation framework. Keywords: middle school, identity, motivation, informal education. 

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2. 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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3. Partnering Middle School Teachers, Industry, and Academic to Bring Engineering to the Science Classroom

   Carrico, C. ; Grohs, J.R. ; Matusovich, H.M. ; Kirk, G.R. ; Schilling, M.R. ( July 2021 , 2021 ASEE Virtual Annual Conference Content Access)

   Despite limited success in broadening participation in engineering with rural and Appalachian youth, there remain challenges such as misunderstandings around engineering careers, misalignments with youth’s sociocultural background, and other environmental barriers. In addition, middle school science teachers may be unfamiliar with engineering or how to integrate engineering concepts into science lessons. Furthermore, teachers interested in incorporating engineering into their curriculum may not have the time or resources to do so. The result may be single interventions such as a professional development workshop for teachers or a career day for students. However, those are unlikely to cause major change or sustained interest development. To address these challenges, we have undertaken our NSF ITEST project titled, Virginia Tech Partnering with Educators and Engineers in Rural Schools (VT PEERS). Through this project, we sought to improve youth awareness of and preparation for engineering related careers and educational pathways. Utilizing regular engagement in engineering-aligned classroom activities and culturally relevant programming, we sought to spark an interest with some students. In addition, our project involves a partnership with teachers, school districts, and local industry to provide a holistic and, hopefully, sustainable influence. By engaging over time we aspired to promote sustainability beyond this NSF project via increased teacher confidence with engineering related activities, continued integration within their science curriculum, and continued relationships with local industry. From the 2017-2020 school years the project has been in seven schools across three rural counties. Each year a grade level was added; that is, the teachers and students from the first year remained for all three years. Year 1 included eight 6th grade science teachers, year 2 added eight 7th grade science teachers, and year 3 added three 8th grade science teachers and a career and technology teacher. The number of students increased from over 500 students in year 1 to over 2500 in year 3. Our three industry partners have remained active throughout the project. During the third and final year in the classrooms, we focused on the sustainable aspects of the project. In particular, on how the intervention support has evolved each year based on data, support requests from the school divisions, and in scaffolding “ownership” of the engineering activities. Qualitative data were used to support our understanding of teachers’ confidence to incorporate engineering into their lessons plans and how their confidence changed over time. Noteworthy, our student data analysis resulted in an instrument change for the third year; however due to COVID, pre and post data was limited to schools who taught on a semester basis. Throughout the project we have utilized the ITEST STEM Workforce Education Helix model to support a pragmatic approach of our research informing our practice to enable an “iterative relationship between STEM content development and STEM career development activities… within the cultural context of schools, with teachers supported by professional development, and through programs supported by effective partnerships.” For example, over the course of the project, scaffolding from the University leading interventions to teachers leading interventions occurred. 

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4. Developing STEM Career Identities among Latinx Youths: Collaborative Design, Evaluations, and Adaptations during COVID-19

   https://doi.org/10.3390/bs13110949  

   Park, Chong Myung ; Donnelly, Hayoung Kim ; Rodriguez, Angelica ; Esquivel, Luis ; Nardi, Cecilia ; Trunfio, Paul ; Oliver-Davila, Alexandra ; Howard, Kimberly A. ; Solberg, V. Scott ( November 2023 , Behavioral Sciences)

   In response to the low representation of Latinx adults in STEM occupations, this community-based participatory action research study aims to increase the number of middle school youths developing STEM career identities and entering high school with the intention to pursue STEM careers. The students were provided with summer and after-school activities focusing on network science and career development curricula. Using a quasi-experimental pretest–posttest design and career narratives, this study examined the changes in STEM and career self-efficacy, as well as career identity. The results show improvements in self-efficacy, an increased number of youths with intentions of pursuing future STEM career opportunities, and deeper reflections on their talents and skills after program participation. This paper also describes the program development and implementation in detail, as well as the adaptations that resulted from COVID-19, for scholars and educators designing similar programs. This study provides promising evidence for the quality of STEM and career development lessons in supporting the emergence of a STEM career identity and self-efficacy.

    

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5. Preparing Rural Middle School Teachers to Implement an Engineering Design Elective Course: A Just-In-Time Professional Development Approach

   https://doi.org/10.18260/1-2--42017  

   Baldwin, Tameshia ; Townsend, Latricia ; Edwards, Callie ( August 2022 , ASEE Conferences)

   This paper presents the experiences of two STEM outreach specialists as they prepared two rural middle school teachers with limited STEM backgrounds to implement a 3-part grade level specific engineering design elective course at their schools. This work is part of an Innovative Experiences for Teachers and Students (ITEST) project designed to provide community-based engineering design experiences for underrepresented middle school students (grades 6-8) from rural N.C. The course engages students in authentic STEM design experiences situated in the advanced manufacturing industry in an effort to improve their STEM content knowledge and career awareness and their self-efficacy, identity and interest in STEM careers, particularly engineering. The outreach specialists experienced a number of challenges as they worked with the teachers, many of which were exacerbated by the on-going pandemic. In response to social distancing requirements imposed by COVID-19, the specialists adopted a just-in-time (JIT) approach to teacher professional development (PD) where the content, pace, and scheduling of PD sessions were based on each individual teacher’s prior content knowledge, comfort level and work schedule. This paper focuses on the process of skill preparation of the middle school teachers in the execution of the 6th grade course in the 2020-21 school year. Additional aspects to be discussed include a sampling of best practices, an overview of lessons learned and implementation strategies during the second iteration of the 6th grade course and the first implementation of the 7th grade course during the 2021-22 school year. 

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