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1. Evaluation of Engineering Problem-framing Professional Development for K-12 Science Teachers

   https://doi.org/10.18260/1-2--34604  

   West, Meg E ; Hylton, J Blake ; Herak, Patrick J ; Wellman, Bruce ; France, Todd ( June 2020 , 2020 ASEE Virtual Annual Conference)

   As the importance to integrate engineering into K12 curricula grows so does the need to develop teachers’ engineering teaching capabilities and knowledge. One method that has been used to aid this development is engineering professional development programs. This evaluation paper presents the successes and challenges of an engineering professional development program for teachers focused around the use of engineering problem-framing design activities in high school science classrooms. These activities were designed to incorporate the cross-cutting ideas published in the Next Generation Science Standards (NGSS) and draw on best practices for instructional design of problem-framing activities from research on design and model-eliciting activities (MEAs). The professional development (PD) was designed to include the following researched-based effective PD key elements: (1) is content focused, (2) incorporates active learning, (3) supports collaboration, (4) uses models of effective practice, (5) provides coaching and expert support, (6) offers feedback and reflection, and (7) is of sustained duration. The engineering PD, including in-classroom deployment of activities and data collection, was designed as an iterative process to be conducted over a three-year period. This will allow for improvement and refinement of our approach. The first iteration, reported in this paper, consisted of seven high school science teachersmore »who have agreed to participate in the PD, implement the problem-framing activities, and collect student data over a period of one year. The PD itself consisted of the teachers comparing science and engineering, participating in problem-framing training and activities, and developing a design challenge scenario for their own courses. The participating teachers completed a survey at the end of the PD that will be used to inform enhancement of the PD and our efforts to recruit additional participants in the following year. The qualitative survey consisted of open-ended questions asking for the most valuable takeaways from the PD, their reasoning for joining the PD, reasons they would or would not recommend the PD, and, in their opinion, what would inspire their colleagues to attend the PD. The responses to the survey along with observations from the team presenting the PD were analyzed to identify lessons learned and future steps for the following iteration of the PD. From the data, three themes emerged: Development of PD, Teacher Motivation, and Teacher Experience.« less
2. Developing Empathy and Persistence through Professional Development in New to CSA Teachers

   https://doi.org/10.1145/3446871.3469793  

   Broneak, Cassandra ; Rosato, Jennifer ( August 2021 , ICER 2021: Proceedings of the 17th ACM Conference on International Computing Education Research)

   To meet the rising demand for computer science (CS) courses, K-12 educators need to be prepared to teach introductory concepts and skills in courses such as Computer Science Principles (CSP), which takes a breadth-first approach to CS and includes topics beyond programming such as data, impacts of computing, and networks. Educators are now also being asked to teach more advanced concepts in courses such as the College Board's Advanced Placement Computer Science A (CSA) course, which focuses on advanced programming using Java and includes topics such as objects, inheritance, arrays, and recursion. Traditional CSA curricula have not used content or pedagogy designed to engage a broad range of learners and support their success. Unlike CSP, which is attracting more underrepresented students to computing as it was designed, CSA continues to enroll mostly male, white, and Asian students [College Board 2019, Ericson 2020, Sax 2020]. In order to expand CS education opportunities, it is crucial that students have an engaging experience in CSA similar to CSP. Well-designed differentiated professional development (PD) that focuses on content and pedagogy is necessary to meet individual teacher needs, to successfully build teacher skills and confidence to teach CSA, and to improve engagement with students [Darling-Hammondmore »2017]. It is critical that as more CS opportunities and courses are developed, teachers remain engaged with their own learning in order to build their content knowledge and refine their teaching practice [CSTA 2020]. CSAwesome, developed and piloted in 2019, offers a College Board endorsed AP CSA curriculum and PD focused on supporting the transition of teachers and students from CSP to CSA. This poster presents preliminary findings aimed at exploring the supports and challenges new-to-CSA high school level educators face when transitioning from teaching an introductory, breadth-first course such as CSP to teaching the more challenging, programming-focused CSA course. Five teachers who completed the online CSAwesome summer 2020 PD completed interviews in spring 2021. The project employed an inductive coding scheme to analyze interview transcriptions and qualitative notes from teachers about their experiences learning, teaching, and implementing CSP and CSA curricula. Initial findings suggest that teachers’ experience in the CSAwesome PD may improve their confidence in teaching CSA, ability to effectively use inclusive teaching practices, ability to empathize with their students, problem-solving skills, and motivation to persist when faced with challenges and difficulties. Teachers noted how the CSAwesome PD provided them with a student perspective and increased feelings of empathy. Participants spoke about the implications of the COVID-19 pandemic on their own learning, student learning, and teaching style. Teachers enter the PD with many different backgrounds, CS experience levels, and strengths, however, new-to-CSA teachers require further PD on content and pedagogy to transition between CSP and CSA. Initial results suggest that the CSAwesome PD may have an impact on long-term teacher development as new-to-CSA teachers who participated indicated a positive impact on their teaching practices, ideologies, and pedagogies.« less
3. Translating and Scaling a Face-to-Face, Video-Based Elementary Science PD Program to an Online Environment

   Kowalski, S. ; Belcastro, A. ; Hvidsten, C. ; Constantine, A. ; Faruqi, F. ; Askinas, K. ; De Vaul, R. ; Roehrig, G. ( April 2021 , Annual Meeting of the NARST International Conference)

   Objective Over the past decade, we developed and studied a face-to-face video-based analysis-of-practice professional development (PD) model. In a cluster randomized trial, we found that the face-to-face model enhanced elementary science teacher knowledge and practice and resulted in important improvements to student science achievement (student treatment effect, d = 0.52; Taylor et al, 2017; Roth et al, 2018). The face-to-face PD model is expensive and difficult to scale. In this paper, we present the results of a two-year design-based research study to translate the face-to-face PD into a facilitated online PD experience. The purpose is to create an effective, flexible, and cost-efficient PD model that will reach a broader audience of teachers. Perspective/Theoretical Framework The face-to-face PD model is grounded in situated cognition and cognitive apprenticeship frameworks. Teachers engage in learning science content and effective science teaching practices in the context in which they will be teaching. There are scaffolded opportunities for teachers to learn from analysis of model videos by experienced teachers, to try teaching model units, to analyze video of their own teaching efforts, and ultimately to develop their own unit, with guidance. The PD model attends to the key features of effective PD as described by Desimonemore »(2009) and others. We adhered closely to the design principles of the face-to-face model as described by Authors, 2019. Methods We followed a design-based research approach (DBR; Cobb et al., 2003; Shavelson et al., 2003) to examine the online program components and how they promoted or interfered with the development of teachers’ knowledge and reflective practice. Of central interest was the examination of mechanisms for facilitating teacher learning (Confrey, 2006). To accomplish this goal, design researchers engaged in iterative cycles of problem analysis, design, implementation, examination, and redesign (Wang & Hannafin, 2005) in phase one of the project before studying its effect. Data Three small pilot groups of teachers engaged in both synchronous and asynchronous components of the larger online course which began implementation with a 10-week summer course that leads into study groups of participants meeting through one academic year. We iteratively designed, tested, and revised 17 modules across three pilot versions. On average, pilot groups completed one module every two weeks. Pilot 1 began the work in May 2019; Pilot 2 began in August 2019, and Pilot 3 began in October 2019. Pilot teachers responded to surveys and took part in interviews related to the PD. The PD facilitators took extensive notes after each iteration. The development team met weekly to discuss revisions. We revised all modules between each pilot group and used what we learned to inform our development of later modules within each pilot. For example, we applied what we learned from testing Module 3 with Pilot 1 to the development of Module 3 for Pilots 2, and also applied what we learned from Module 3 with Pilot 1 to the development of Module 7 for Pilot 1. Results We found that community building required the same incremental trust-building activities that occur in face-to-face PD. Teachers began with low-risk activities and gradually engaged in activities that required greater vulnerability (sharing a video of themselves teaching a model unit for analysis and critique by the group). We also identified how to contextualize technical tools with instructional prompts to allow teachers to productively interact with one another about science ideas asynchronously. As part of that effort, we crafted crux questions to surface teachers’ confusions or challenges related to content or pedagogy. We called them crux questions because they revealed teachers’ uncertainty and deepened learning during the discussion. Facilitators leveraged asynchronous responses to crux questions in the synchronous sessions to push teacher thinking further than would have otherwise been possible in a 2-hour synchronous video-conference. Significance Supporting teachers with effective, flexible, and cost-efficient PD is difficult under the best of circumstances. In the era of covid-19, online PD has taken on new urgency. NARST members will gain insight into the translation of an effective face-to-face PD model to an online environment.« less
4. Creating Biologically Inspired Design Units for High School Engineering Courses

   https://doi.org/10.1109/FIE49875.2021.9637238  

   Moore, Roxanne A. ; Ehsan, Hoda ; Kim, Euisun ; Helms, Michael ; Alemdar, Meltem ; Rosen, Jeffrey ; Cappelli, Christopher J. ; Weissburg, Marc ( December 2021 , Institute of Electrical and Electronics Engineers Frontiers in Engineering Educario)

   This innovative practice work in progress paper presents the Biologically Inspired Design for Engineering Education (BTRDEE) project, to create socially relevant, accessible, highly-contextualized biologically inspired design experiences that can be disseminated to high school audiences engineering audiences in Georgia and nationally. Curriculum units arc 6-10 weeks in duration and will meet many standards for high school engineering courses in Georgia. There will be three curriculum units (one for each engineering course in the 3-course pathway), each building skills in engineering design and specific skills for BID. Currently in its second year, BIRDEE has developed its first unit of curriculum and has hosted its first professional development with 4 pilot teachers in the summer of 2020. The BIRDEE curriculum situates challenges within socially relevant contexts and provides cutting-edge biological scenarios to ignite creative and humanistic engineering experiences to 1) drive greaterengagement in engineering, particularly among women, 2) improve student engineering skills, especially problem definition and ideation skills, and 3) increase students awareness of the connection and impacts between the engineered and living worlds. This paper describes the motivation for the BIRDEE project, the learning goals for the curriculum, and a description of the first unit. We provide reflections and feedback frommore »teacher work and focus groups during our summer professional development and highlight the challenges associated with building BID competency across biology and engineering to equip teachers with the skills they need to teach the BIRDEE units. These lessons can be applied to teaching BID more broadly, as its multidisciplinary nature creates challenges (and opportunities) for teaching and learning engineering design.« less
5. Implementing and Assessing a Joint REU/RET Program in Materials Science

   Salzman, Noah ; Nadelson, Louis ; Ubic, Rick ( January 2016 , ASEE Annual Conference and Exposition)

   In this paper we describe a joint Research Experience for Undergraduates (REU) and Research Experience for Teachers (RET) program focused on energy and sustainability topics within a Materials Science and Engineering program at a public university. This program brought ten undergraduate science and engineering students and five local middle and high school teachers on campus for an 8-week research experiences working with different lab groups. Given the relatively small number of participants, we chose qualitative interviews as our primary source of data for assessing the effectiveness of this program. The participants identified numerous positive aspects of participating in the summer research program. Students appreciated the sense of community they developed with both the other participants in the research program and the other members of their lab groups. Although most of the participants did not report the summer research experience as having a strong influence on their decisions to pursue graduate school or careers involving research, they did report both being more confident in their ability to be successful as a researcher and appreciating the opportunity to learn more about the practice of engineering research in an academic setting. For the teachers involved in the program we describe how participation influencedmore »their leadership, perceptions of adoption educational innovations, and willingness to provide more opportunities to engage their students in authentic STEM research. The participants also provided several recommendations for improvement to the summer research program. For the students, these included more materials in advance and a more streamlined onboarding process to allow them to get up to speed on their projects more quickly, consistent access to their supervisors, and work that is intellectually challenging. Suggestion from the teacher participants for improvement mostly involved requests for more guidance on how to incorporate what they were learning in their research into lessons for their classrooms. By describing this program and the successes and challenges encountered by the participants and organizers, we intend to help others considering implementing REU/RET programs or other summer research experiences to design and implement successful programs.« less