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1. INVESTIGATION OF THE POST-PANDEMIC STEM EDUCATION (STEM 3.0)

   KHALID H. TANTAWI, JARED ASHCROFT (October 2022, Journal of advanced technological education)

   Peter Kazarinoff (Ed.)

   In this work, we analyze the lessons learned from the CoVid-19 pandemic and the prospects of the science education that evolved as a result of the pandemic. The two primary shortcomings that arose during the pandemic include: the poor presence of cross-boundary and interdisciplinary research as evidenced by the urgency in establishing cross-boundary research groups in the early days of the pandemic, and the lack of understanding of the scientific method in the general public as evidenced, for example, by the worldwide Hydroxychloroquine events of 2020. An effective approach to solving these shortcomings is increasing innovative research at the two-year tertiary education level. The focus of continuing technical education will shift towards technologies that provide self-sufficiency, such as artificial intelligence, intelligent robotics, augmented reality, digital twins, and additive manufacturing. These features likely constitute the cornerstone of the upcoming science education paradigm, which we denominate "STEM 3.0". 

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2. Improving STEM education: The design and development of a K-12 STEM observation protocol (STEM-OP).

   Dare, E.A.; Hiwatig, B.; Karatithamkul, K.; Ellis, J.A.; Roehrig, G.H.; Ring-Whalen, E.A.; Rouleau, M.D.; Faruqi, F.; Rice, C.; Titu, P.; et al (January 2021, ASEE Annual Conference proceedings)

   null (Ed.)

   Integrated approaches to teaching science, technology, engineering, and mathematics (commonly referred to as STEM education) in K-12 classrooms have resulted in a growing number of teachers incorporating engineering in their science classrooms. Such changes are a result of shifts in science standards to include engineering as evidenced by the Next Generation Science Standards. To date, 20 states and the District of Columbia have adopted the NGSS and another 24 have adopted standards based on the Framework for K-12 Science Education. Despite the increased presence of engineering and integrated STEM education in K-12 education, there are several concerns to consider. One concern is the limited availability of observation instruments appropriate for instruction where multiple STEM disciplines are present and integrated with one another. Addressing this concern requires the development of a new observation instrument, designed with integrated STEM instruction in mind. An instrument such as this has implications for both research and practice. For example, research using this instrument could help educators compare integrated STEM instruction across grade bands. Additionally, this tool could be useful in the preparation of pre-service teachers and professional development of in-service teachers new to integrated STEM education and formative learning through professional learning communities or classroom coaching. The work presented here describes in detail the development of an integrated STEM observation instrument that can be used for both research and practice. Over a period of approximately 18-months, a team of STEM educators and educational researchers developed a 10-item integrated STEM observation instrument for use in K-12 science and engineering classrooms. The process of developing the instrument began with establishing a conceptual framework, drawing on the integrated STEM research literature, national standards documents, and frameworks for both K-12 engineering education and integrated STEM education. As part of the instrument development process, the project team had access to over 2000 classroom videos where integrated STEM education took place. Initial analysis of a selection of these videos helped the project team write a preliminary draft instrument consisting of 52 items. Through several rounds of revisions, including the construction of detailed scoring levels of the items and collapsing of items that significantly overlapped, and piloting of the instrument for usability, items were added, edited, and/or removed for various reasons. These reasons included issues concerning the intricacy of the observed phenomenon or the item not being specific to integrated STEM education (e.g., questioning). In its final form, the instrument consists of 10 items, each comprising four descriptive levels. Each item is also accompanied by a set of user guidelines, which have been refined by the project team as a result of piloting the instrument and reviewed by external experts in the field. The instrument has shown to be reliable with the project team and further validation is underway. This instrument will be of use to a wide variety of educators and educational researchers looking to understand the implementation of integrated STEM education in K-12 science and engineering classrooms. 

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3. Improving Integrated STEM Education: The Design and Development of a K-12 STEM Observation Protocol (STEM-OP) (RTP)

   Dare, E. A.; Hiwatig, B.; Keratithamkul, K.; Ellis, J. A.; Roehrig, G. H.; Ring-Whalen, E. A.; Rouleau, M. D.; Faruqi, F.; Rice, C.; Titu, P.; et al (January 2021, ASEE Annual Conference proceedings)

   null (Ed.)

   Integrated approaches to teaching science, technology, engineering, and mathematics (commonly referred to as STEM education) in K-12 classrooms have resulted in a growing number of teachers incorporating engineering in their science classrooms. Such changes are a result of shifts in science standards to include engineering as evidenced by the Next Generation Science Standards. To date, 20 states and the District of Columbia have adopted the NGSS and another 24 have adopted standards based on the Framework for K-12 Science Education. Despite the increased presence of engineering and integrated STEM education in K-12 education, there are several concerns to consider. One concern is the limited availability of observation instruments appropriate for instruction where multiple STEM disciplines are present and integrated with one another. Addressing this concern requires the development of a new observation instrument, designed with integrated STEM instruction in mind. An instrument such as this has implications for both research and practice. For example, research using this instrument could help educators compare integrated STEM instruction across grade bands. Additionally, this tool could be useful in the preparation of pre-service teachers and professional development of in-service teachers new to integrated STEM education and formative learning through professional learning communities or classroom coaching. The work presented here describes in detail the development of an integrated STEM observation instrument - the STEM Observation Protocol (STEM-OP) - that can be used for both research and practice. Over a period of approximately 18-months, a team of STEM educators and educational researchers developed a 10-item integrated STEM observation instrument for use in K-12 science and engineering classrooms. The process of developing the STEM-OP began with establishing a conceptual framework, drawing on the integrated STEM research literature, national standards documents, and frameworks for both K-12 engineering education and integrated STEM education. As part of the instrument development process, the project team had access to over 2000 classroom videos where integrated STEM education took place. Initial analysis of a selection of these videos helped the project team write a preliminary draft instrument consisting of 79 items. Through several rounds of revisions, including the construction of detailed scoring levels of the items and collapsing of items that significantly overlapped, and piloting of the instrument for usability, items were added, edited, and/or removed for various reasons. These reasons included issues concerning the intricacy of the observed phenomenon or the item not being specific to integrated STEM education (e.g., questioning). In its final form, the STEM-OP consists of 10 items, each comprising four descriptive levels. Each item is also accompanied by a set of user guidelines, which have been refined by the project team as a result of piloting the instrument and reviewed by external experts in the field. The instrument has shown to be reliable with the project team and further validation is underway. The STEM-OP will be of use to a wide variety of educators and educational researchers looking to understand the implementation of integrated STEM education in K-12 science and engineering classrooms. 

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4. Technology-Supported Science Instruction Through Integrated STEM Guitar Building: The Case for STEM and Non-STEM Instructor Success

   Hauze, Sean; French, Debbie (January 2017, Contemporary issues in technology and teacher education)

   With a national emphasis on integrated science, technology, engineering, and mathematics (STEM) education in K-16 courses, incorporating technology in a meaningful way is critical. This research examines whether STEM and non-STEM teachers were able to incorporate technology in STEM courses successfully with sufficient professional development. The teachers in this study consisted of faculty from middle schools, high schools, and colleges recruited for STEM Guitar Building institutes held between 2013 and 2016. Each teacher participated in a 50-hour professional development opportunity in the manufacture of a solid-body electric guitar and received instruction on how to teach integrated STEM Modular Learning Activities (MLAs), which are aligned with the Common Core mathematics standards and the Next Generation Science Standards (NGSS). The data collected include pre- and postassessment from 769 students in three grade bands (grades 6-8, 9-12, and undergraduate level from 15 states). The results showed statistically significant gains at the p < 0.05 level across all 12 of the core MLAs, with no statistically significant difference between STEM and non-STEM instructors for all except two MLAs. The two MLAs that did reveal a statistically significant difference were more technical—Set Up and Computer Aided Design/Computer Aided Manufacturing Systems (CAD/CAM). These results show non-STEM and STEM teachers alike in this study were able to successfully incorporate technology in NGSS-aligned integrated STEM lessons, as evidenced by student learning gains. 

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5. Justice‐centered STEM education with multilingual learners to address societal challenges: A conceptual framework

   https://doi.org/10.1002/tea.21999  

   Lee, Okhee; Grapin, Scott (October 2024, Journal of Research in Science Teaching)

   Abstract We propose a conceptual framework for STEM education that is centered around justice for minoritized groups. Justice‐centered STEM education engages all students in multiple STEM subjects, including data science and computer science, to explain and design solutions to societal challenges disproportionately impacting minoritized groups. We articulate the affordances of justice‐centered STEM education for one minoritized student group that has been traditionally denied meaningful STEM learning: multilingual learners (MLs). Justice‐centered STEM education with MLs leverages the assets they bring to STEM learning, including their transnational experiences and knowledge as well as their rich repertoire of meaning‐making resources. In this position paper, we propose our conceptual framework to chart a new research agenda on justice‐centered STEM education to address societal challenges with all students, especially MLs. Our conceptual framework incorporates four interrelated components by leveraging the convergence of multiple STEM disciplines to promote justice‐centered STEM education with MLs: (a) societal challenges in science education, (b) justice‐centered data science education, (c) justice‐centered computer science education, and (d) justice‐centered engineering education. The article illustrates our conceptual framework using the case of the COVID‐19 pandemic, which has presented an unprecedented societal challenge but also an unprecedented opportunity to cultivate MLs' assets toward promoting justice in STEM education. Finally, we describe how our conceptual framework establishes the foundation for a new research agenda that addresses increasingly complex, prevalent, and intractable societal challenges disproportionately impacting minoritized groups. We also consider broader issues pertinent to our conceptual framework, including the social and emotional impacts of societal challenges; the growth of science denial and misinformation; and factors associated with politics, ideology, and religion. Justice‐centered STEM education contributes to solving societal challenges that K‐12 students currently face while preparing them to shape a more just society. 

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