Early science, technology, engineering, and mathematics (STEM) education sets the stage for future STEM learning. The purpose of this synthesis is to understand the findings from investments to improve prekindergarten (preK) and elementary science teaching from projects funded by the National Science Foundation’s Discovery Research PreK-12 (DRK-12) program. In the 5 years spanning 2011–15, the DRK-12 program funded or cofunded 25 projects, totaling more than $60 million, related to improving preK and elementary science teaching. Our review identified 25 DRK-12 projects related to improving preK and elementary science teaching funded in 2011–15. We synthesized findings from 25 of those projects that produced products (e.g., peer-reviewed journal articles, conference papers) that described the project and outcomes. We synthesized the empirical findings from interventions in four common areas of investment: (a) preservice preK and elementary preparation programs, (b) in-service teacher professional development (PD), (c) instructional materials for preK and elementary teachers, and (d) strategies for diverse learners. Link to PDF: https://www.air.org/sites/default/files/2022-08/Improving-Prek-and-Elementary-Science-Teaching--DRK-12-STEM-August-2022.pdf
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Just keep swimming: Increasing resilience of STEM preservice teachers during COVID-19
A substantial achievement gap between K-12 English learners (ELs) and non-ELs in
science, technology, engineering, and mathematics (STEM) content areas exists, as indicated by national assessments of student outcomes. Considering the expected steady increase in students who are ELs in the U.S., determining methods for addressing this achievement gap is of immediate concern. Research has indicated this gap may be exacerbated by lack of adequate teacher preparation, specifically in STEM fields, to effectively teach students who are culturally and linguistically diverse (CLD). Founded in previous research about effective teacher preparation, the current case study pilots and reports on a model of early STEM preservice teacher training that integrates: knowledge of language development for ELs, early experiences with CLD learners, and professional development activities that guide the implementation of STEM pedagogical methods. Five STEM preservice teachers participated in a year-long supplemental training program focused on adapting STEM instruction for ELs. Components of the supplemental program included: (a) coursework extending teacher knowledge of EL language development, (b) fieldwork providing early exposure to research-based teaching experiences with EL students, and (c) professional development guiding the creation of hands-on
STEM curriculum for diverse learners. Five secondary preservice teachers experienced increases in self-efficacy, growth in STEM instructional practices, and greater motivation for teaching in high-need schools. Results will inform educational models for improving STEM-EL teaching, thereby addressing a crucial need to serve the growing national population of underserved students.
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- Award ID(s):
- 1852890
- NSF-PAR ID:
- 10426516
- Date Published:
- Journal Name:
- Journal of instructional pedagogies
- Volume:
- 28
- ISSN:
- 1941-3394
- Page Range / eLocation ID:
- 1-28
- Format(s):
- Medium: X
- Sponsoring Org:
- National Science Foundation
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Abstract To prepare preservice secondary science teachers to teach English learners (ELs), teacher education programs must provide sustained coursework and experiences in principles and strategies found effective in supporting ELs’ learning of science. In the context of a teacher education program recognized for its attention to ELs, we investigated seven preservice secondary science teachers’ understanding of academic language and of how to support EL students’ use of academic language. More specifically, over the course of their 13‐month program, we examined changes in (a) preservice teachers’ understanding of the three levels of academic language (i.e., lexical, or vocabulary; syntactic, or sentence; and discursive, or message) and (b) the types of instructional support they reported using at each level (e.g., peer collaboration at the discursive level). We also compared their understanding of academic language and instructional support both to their experienced cooperating teachers’ understanding and to their actual classroom practice. From qualitative analysis of data collected, we found that preservice teachers understood academic language as more than just vocabulary—as spanning lexical, syntactic, and discursive levels—although they reported implementing more types of supports at the lexical and discursive levels than at the syntactic level. We also found that preservice teacher participants’ understanding of academic language and instructional support resonated with that of their cooperating teachers and with their own classroom practice. We close with discussion of ways teacher education programs can deepen and broaden preservice secondary science teachers’ understanding of the role of academic language in ELs’ science learning
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As K-12 engineering education becomes more ubiquitous in the U.S, increased attention has been paid to preparing the heterogeneous group of in-service teachers who have taken on the challenge of teaching engineering. Standards have emerged for professional development along with research on teacher learning in engineering that call for teachers to facilitate and support engineering learning environments. Given that many teachers may not have experienced engineering practice calls have been made to engage teaches K-12 teachers in the “doing” of engineering as part of their preparation. However, there is a need for research studying more specific nature of the “doing” and the instructional implications for engaging teachers in “doing” engineering. In general, to date, limited time and constrained resources necessitate that many professional development programs for K-12 teachers to engage participants in the same engineering activities they will enact with their students. While this approach supports teachers’ familiarity with curriculum and ability to anticipate students’ ideas, there is reason to believe that these experiences may not be authentic enough to support teachers in developing a rich understanding of the “doing” of engineering. K-12 teachers are often familiar with the materials and curricular solutions, given their experiences as adults, which means that engaging in the same tasks as their students may not be challenging enough to develop their understandings about engineering. This can then be consequential for their pedagogy: In our prior work, we found that teachers’ linear conceptions of the engineering design process can limit them from recognizing and supporting student engagement in productive design practices. Research on the development of engineering design practices with adults in undergraduate and professional engineering settings has shown significant differences in how adults approach and understand problems. Therefore, we conjectured that engaging teachers in more rigorous engineering challenges designed for adult engineering novices would more readily support their developing rich understandings of the ways in which professional engineers move through the design process. We term this approach meaningful engineering for teachers, and it is informed by work in science education that highlights the importance of learning environments creating a need for learners to develop and engage in disciplinary practices. We explored this approach to teachers’ professional learning experiences in doing engineering in an online graduate program for in-service teachers in engineering education at Tufts University entitled the Teacher Engineering Education Program (teep.tufts.edu). In this exploratory study, we asked: 1. How did teachers respond to engaging in meaningful engineering for teachers in the TEEP program? 2. What did teachers identify as important things they learned about engineering content and pedagogy? This paper focuses on one theme that emerged from teachers’ reflections. Our analysis found that teachers reported that meaningful engineering supported their development of epistemic empathy (“the act of understanding and appreciating someone's cognitive and emotional experience within an epistemic activity”) as a result of their own affective experiences in doing engineering that required significant iteration as well as using novel robotic materials. We consider how epistemic empathy may be an important aspect of teacher learning in K-12 engineering education and the potential implications for designing engineering teacher education.more » « less
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Abstract This study applies psychological models of interest and motivation (i.e., a model of interest‐development and self‐determination theory) to the experiences of six preservice science Noyce scholars who participated in a teacher preparation program. The National Science Foundation's Noyce grant aims to incentivize mathematics and science majors to teach in high‐needs school districts. Through this interview study, we sought to understand how Noyce scholars' pre‐existing interests and their experiences in the Noyce program interact to develop individual commitments to teach in high‐needs school settings. Case studies reveal that scholars had no prior experiences in high‐needs schools, abstract ideas about teachers, students, and resources in these contexts, and varying degrees of initial connectedness to teaching in high‐needs school settings. Scholars found that site visits to diverse high‐needs schools (i.e., rural and urban) triggered their interest to teach in similar contexts. Preservice science teachers' emerging interest and level of commitment to teaching in high‐needs schools following the teacher preparation program was dependent upon context‐specific mastery experiences and autonomy within their long‐term clinical field experience. This study offers implications for teacher educators who are recruiting and preparing students to teach in high‐needs school contexts.
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