Knowing how science teachers develop their professional knowledge has been a challenge. One potential way to determine the professional knowledge of teachers is through videos. In the study described here, the authors recruited 60 elementary and secondary science teachers, showed them one of two 10‐min videos, and recorded and analyzed their comments when watching the videos. The coding focused on their noticing of student learning, teacher's teaching, types of teaching practices, and the use of interpretative frames. The noticing data were collected and analyzed to determine the differences between groups of teachers. The findings from the analysis indicated that most science teachers noticed the instruction of teachers rather than the learning of students, and these noticing events were often focused on general instructional practices as opposed to the science practices emphasized in the
- Award ID(s):
- 1908431
- NSF-PAR ID:
- 10475405
- Publisher / Repository:
- Wiley-Blackwell
- Date Published:
- Journal Name:
- School Science and Mathematics
- Volume:
- 124
- Issue:
- 3
- ISSN:
- 0036-6803
- Format(s):
- Medium: X Size: p. 159-170
- Size(s):
- p. 159-170
- Sponsoring Org:
- National Science Foundation
More Like this
-
In order to create professional development experiences, curriculum materials, and policies that support elementary school teachers to embed computational thinking (CT) in their teaching, researchers and teacher educators must under- stand ways teachers see CT as connecting to their classroom practices. Taking the viewpoint that teachers’ initial ideas about CT can serve as useful resources on which to build ed- ucational experiences, we interviewed 12 elementary school teachers to probe their understanding of six components of CT (abstraction, algorithmic thinking, automation, debug- ging, decomposition, and generalization) and how those com- ponents relate to their math and science teaching. Results suggested that teachers saw stronger connections between CT and their mathematics instruction than between CT and their science instruction. We also found that teachers draw upon their existing knowledge of CT-related terminology to make connections to their math and science instruction that could be leveraged in professional development. Teachers were, however, concerned about bringing CT into teaching due to limited class time and the difficulties of addressing high level CT in developmentally appropriate ways. We discuss these results and their implications future research and the design of professional development, sharing examples of how we used teachers’ initial ideas as the foundation of a workshop introducing them to computational thinking.more » « less
-
Instructional shifts required by equitable, reform‐based science instruction are challenging, especially in the elementary context. Such shifts require professional development (PD) that supports teacher internalization of new pedagogical strategies as well as changes in beliefs about how students learn. Because of this complexity, many PD programs struggle to foster lasting pedagogical shifts, necessitating further investigation into why some teachers successfully embrace reform practices while others do not. This qualitative study uses a nonlinear, iterative model of teacher learning (Interconnected Model of Professional Growth; Clarke & Hollingsworth, 2002) alongside professional noticing to help understand why elementary teachers in science PD differentially make sense of and internalize new pedagogies. Findings indicate that teachers most likely to adopt reform‐based instructional practices from the PD were those who clearly connected student learning to their instructional moves. In addition, teachers who more actively attended to student sensemaking and productive struggle took up pedagogies from the PD more substantively than did colleagues who attended solely to student engagement and affect. Finally, teachers who attended to and valued novel ideas from students’ lived experiences were more likely to change their beliefs about students’ capacity to learn science, and thus more likely to see the value of instructional practices from the PD. In sum, structuring PD to build on these specific teacher noticing skills can encourage more teachers to move away from traditional, teacher‐directed instructional practice, and more fully support reform‐based instructional practices.more » « less
-
n this paper we described the process of four in-service elementary school teachers learning coding in a blended professional learning course developed and delivered through a federally funded research practice partnership project. We focused on the collective nature of learning and use activity theory (Engeström, 1999) to analyze connections among mediations, contradictions, and meaningful practices that were occurring for teachers in the course over time. The results showed that professional learning programs to support elementary teachers’ implementation of robotics and coding teaching and learning can systematically foster teachers’ collaboration in learning coding/robotics and developing lesson activities incorporating coding and robotics in meaningful ways in the day to day curriculum and teaching in their elementary classrooms.more » « less
-
Reform efforts targeting science instruction emphasize that students should develop scientific proficiency that empowers them to collaboratively negotiate science ideas as they develop meaningful understandings about science phenomena through science practices. The lessons teachers design and enact play a critical role in engaging students in rigorous science learning. Collaborative design, in which teachers work together to design, enact, and reflect on their teaching, holds potential to support teachers’ learning, but scarce research examines the pathways by which collaborative design can influence teachers’ instructional practices. Examining the teaching and reflective thinking of two science teachers who engaged in collaborative design activities over two years, we found that their enactment practices became more supportive of students’ rigorous learning over time, and that they identified collaborative efforts with teacher educators and partner teachers to plan lessons and analyze videos of instruction as supportive of their learning to enact rigorous instruction.more » « less
-
The benefits of using video in teacher education as a tool for reflection and for developing professional expertise have long been recognized. Recent introduction of 360 video technology holds promise to extend these benefits as it allows prospective teachers to reflect on their own performance by considering the classroom from multiple perspectives. This study examined nine prospective secondary teachers’ (PSTs) noticing and self-reflection on the 360 recordings of their own teaching. The PSTs, enrolled in a capstone course Mathematical Reasoning and Proving for Secondary Teachers, taught a proof-oriented lesson to small groups of students in local schools while capturing their teaching with 360 video cameras. We analyzed the PSTs’ written comments on their video and reflection reports to identify the categories of noticing afforded by the 360 technology as well as the instances of PSTs’ learning. The results point to the powerful potential of 360 videos for supporting PSTs’ self-reflection and professional growth.more » « less