More Like this

1. Empowering Elementary Students with Community-Based Engineering: A Teacher’s Experience in a Rural School District

   https://doi.org/10.3390/educsci13050434  

   Boz, Tugba; Hammack, Rebekah; Lux, Nicholas; Gannon, Paul (May 2023, Education Sciences)

   This paper presents a case study of an elementary teacher, Holly, who participated in a federally funded summer professional development (PD) program aimed at integrating community-based engineering into elementary education. The study examines how Holly’s teaching practices and beliefs about teaching engineering contributed to the significant improvements in her students’ attitudes toward engineering and their perceptions of engineering as a potential career. Data were collected over three years through multiple methods, including post-PD interviews, lesson recordings, and a post-teaching interview. We analyzed classroom videos using a video analysis protocol. We used open coding to analyze the interviews. Once the analysis of the interviews and videos was completed, we engaged in a sense-making process to identify connections across data points (videos and interviews). Our findings showed that Holly extensively incorporated scientific inquiry into her lessons. This approach enabled students to develop their inquiry skills and facilitated a smooth transition to engineering design activities. By connecting class activities to the local context, students were able to see the relevance of engineering to their everyday lives and take ownership of their learning. This study emphasizes the potential of community-focused engineering to foster meaningful science and engineering practices in elementary education. 

   more » « less
2. A Professional Development Model to Integrate Computational Thinking Into Middle School Science Through Codesigned Storylines

   Biddy, Q.; Gendreau Chakarov, A.; Bush, J.; Hennessy Elliott, C.; Jacobs, J.; Recker, M.; Sumner, T.; Penuel, W. (March 2021, Contemporary issues in technology and teacher education)

   This article describes a professional development (PD) model, the CT-Integration Cycle, that supports teachers in learning to integrate computational thinking (CT) and computer science principles into their middle school science and STEM instruction. The PD model outlined here includes collaborative design (codesign; Voogt et al., 2015) of curricular units aligned with the Next Generation Science Standards (NGSS) that use programmable sensors. Specifically, teachers can develop or modify curricular materials to ensure a focus on coherent, student-driven instruction through the investigation of scientific phenomena that are relevant to students and integrate CT and sensor technology. Teachers can implement these storylines and collaboratively reflect on their instructional practices and student learning. Throughout this process, teachers may develop expertise in CT-integrated science instruction as they plan and use instructional practices aligned with the NGSS and foreground CT. This paper describes an examination of a group of five middle school teachers’ experiences during one iteration of the CT-Integration Cycle, including their learning, planning, implementation, and reflection on a unit they codesigned. Throughout their participation in the PD, the teachers expanded their capacity to engage deeply with CT practices and thoughtfully facilitated a CT-integrated unit with their students. 

   more » « less
3. A Professional Development Model to Integrate Computational Thinking Into Middle School Science Through Codesigned Storylines

   Biddy, Q.; Gendreau Chakarov, A.; Bush, J.; Hennessy Elliott, C.; Jacobs, J.; Recker, M.; Sumner, T.; Penuel, W. (January 2021, Contemporary issues in technology and teacher education)

   null (Ed.)

   This article describes a professional development (PD) model, the CT- Integration Cycle, that supports teachers in learning to integrate computational thinking (CT) and computer science principles into their middle school science and STEM instruction. The PD model outlined here includes collaborative design (codesign; Voogt et al., 2015) of curricular units aligned with the Next Generation Science Standards (NGSS) that use programmable sensors. Specifically, teachers can develop or modify curricular materials to ensure a focus on coherent, student-driven instruction through the investigation of scientific phenomena that are relevant to students and integrate CT and sensor technology. Teachers can implement these storylines and collaboratively reflect on their instructional practices and student learning. Throughout this process, teachers may develop expertise in CT-integrated science instruction as they plan and use instructional practices aligned with the NGSS and foreground CT. This paper describes an examination of a group of five middle school teachers’ experiences during one iteration of the CT- Integration Cycle, including their learning, planning, implementation, and reflection on a unit they codesigned. Throughout their participation in the PD, the teachers expanded their capacity to engage deeply with CT practices and thoughtfully facilitated a CT-integrated unit with their students. 

   more » « less
4. Modeling 3D Plants: Student Achievement Through Productive Failure

   Arango-Caro, Sandra; Langewisch, Tiffany; Ying, Kaitlyn; Arellano_Haberberger, Michelle; Callis-Duehl, Kristine (October 2023, Society for the Advancement of Biology Education Research (SABER) Midwest)

   To be successful in their future careers, students must be able to process information, devise creative solutions, and apply previous knowledge to new situations. Learning through only traditional teaching practices that rely heavily on lecture format and memorization is insufficient to prepare students for the future. Interactive project-based learning that experiences productive failure provides the opportunity for students to problem-solve novel topics and potentially fail at finding the solution. Through explanation, elaboration, comparison of iterations, refinement, and implementations, students can be more prepared to solve future problems. Our study examined the benefits of productive failure on high school students from both formal and informal learning environments working in collaborative teams to design and create 3D plant models. This STEAM project integrates science, design, and technology through innovative learning experiences in plant and agricultural science using emergent technologies. This learning experience encourages students to work together in collaborative teams of self-identified science, technophile, and art students to create 3D models of plants used in research at the Donald Danforth Plant Science Center in St. Louis, MO. Students learn about scientific research, the importance of plants in our society, and practice science communication skills. To create the 3D models, students must learn-by-doing to become proficient in using previously unfamiliar 3D modeling software where their teachers are merely facilitators. Students become active participants in their own learning by overcoming challenges through research, troubleshooting, teamwork, and perseverance. We used a mixed-method assessment approach comparing pre- and post-reflection questions. Students experience many challenges with learning the 3D model programs. They reported that they overcame difficulties working with the 3D modeling programs primarily through help from others and consulting outside resources, such as YouTube videos, as well as through continued effort. Students indicated that they faced challenges when creating their models but recognized that this project was a learning experience. Productive failure through the process of struggling and learning from one’s mistakes can encourage positive learning outcomes and give students a better ability to overcome future challenges. 

   more » « less
5. Modeling 3D Plants: Student Achievement Through Productive Failure

   Arango-Caro, S; Langewisch, T; Ying, K; Arellano, M; Callis-Duehl, K. (October 2023, Society for the Advancement of Biology Education Research (SABER) Midwest)

   To be successful in their future careers, students must be able to process information, devise creative solutions, and apply previous knowledge to new situations. Learning through only traditional teaching practices that rely heavily on lecture format and memorization is insufficient to prepare students for the future. Interactive project-based learning that experiences productive failure provides the opportunity for students to problem-solve novel topics and potentially fail at finding the solution. Through explanation, elaboration, comparison of iterations, refinement, and implementations, students can be more prepared to solve future problems. Our study examined the benefits of productive failure on high school students from both formal and informal learning environments working in collaborative teams to design and create 3D plant models. This STEAM project integrates science, design, and technology through innovative learning experiences in plant and agricultural science using emergent technologies. This learning experience encourages students to work together in collaborative teams of self-identified science, technophile, and art students to create 3D models of plants used in research at the Donald Danforth Plant Science Center in St. Louis, MO. Students learn about scientific research, the importance of plants in our society, and practice science communication skills. To create the 3D models, students must learn-by-doing to become proficient in using previously unfamiliar 3D modeling software where their teachers are merely facilitators. Students become active participants in their own learning by overcoming challenges through research, troubleshooting, teamwork, and perseverance. We used a mixed-method assessment approach comparing pre- and post-reflection questions. Students experience many challenges with learning the 3D model programs. They reported that they overcame difficulties working with the 3D modeling programs primarily through help from others and consulting outside resources, such as YouTube videos, as well as through continued effort. Students indicated that they faced challenges when creating their models but recognized that this project was a learning experience. Productive failure through the process of struggling and learning from one’s mistakes can encourage positive learning outcomes and give students a better ability to overcome future challenges. 

   more » « less