The Next Generation Science Standards (NGSS) identify an ambitious progression for learning energy, beginning in elementary school. To help the nation's teachers address this challenge, this project will develop and investigate the opportunities and limitations of Focus on Energy, a professional development (PD) system for elementary teachers (grades 3-5). The PD will contain: resources that will help teachers to interpret, evaluate and cultivate students' ideas about energy; classroom activities to help them to identify, track and represent energy forms and flows; and supports to help them in engaging students in these activities. Teachers will receive the science and pedagogical content knowledge they need to teach about energy in a crosscutting way across all their science curricula; students will be intellectually engaged in the practice of developing, testing, and revising a model of energy they can use to describe phenomena both in school and in their everyday lives; and formative assessment will guide the moment-by-moment advancement of students' ideas about energy. This project will develop and test a scalable model of PD that will enhance the ability of in-service early elementary teachers to help students learn energy concepts by coordinating formative assessment, face-to-face and web-based PD activities. Researchers will develop and iteratively refine tools to assess both teacher and student energy reasoning strategies. The goals of the project include (1) teachers' increased facility with, and disciplined application of, representations and energy reasoning to make sense of everyday phenomena in terms of energy; (2) teachers' increased ability to interpret student representations and ideas about energy to make instructional decisions; and (3) students' improved use of representations and energy reasoning to develop and refine models that describe energy forms and flows associated with everyday phenomena. The web-based product will contain: a set of formative assessments to help teachers to interpret student ideas about energy based on the Facets model; a series of classroom tested activities to introduce the Energy Tracking Lens (method to explore energy concept using multiple representations); and videos of classroom exemplars as well as scientists thinking out loud while using the Energy Tracking Lens. The project will refine the existing PD and build a system that supports online implementation by constructing a facilitator's guide so that the online community can run with one facilitator.
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TEAM MEMBERS:
Sara LacyRoger TobinNathaniel BrownStamatis VokosRachel ScherrKara GrayLane SeeleyAmy Robertson
This Phase I SEPA proposal supports a consortium of science and education partners that will develop System Dynamics (SD) computer models to illustrate basic health science concepts. The consortium includes Oregon Health Sciences University (OHSU), Portland Public Schools (PPS), Saturday Academy, and the Portland VA Medical Center. SD is a computer modeling technique in which diagrams illustrate system structure and simulations illustrate system behavior. Desktop computers and commercial software packages allow SD to be applied with considerable success in K-12 education. NSF grants to Portland Public Schools have trained over 225 high school teachers in Portland and surrounding areas. Two magnet programs have been established with an emphasis on systems and at least five other schools offer significant systems curriculum. Major components of this project include (1) Annual summer research internships at OHSU for high school teachers and high school students, (2) Development of SD models relevant to each research project, (3) Ongoing interactions between high school science programs and OHSU research laboratories, (4) Development of curriculum materials to augment the use of the SD model in the high school classroom or laboratory setting, and (5) Development of video materials to support the classroom teacher. Content will focus on four fundamental models: linear input/exponential output, bi-molecular binding (association/dissociation), population dynamics, and homeostasis. Each of these models is very rich and may be extended to a broad variety of research problems. In addition these models may be combined, for example to illustrate the effect of drugs (binding model) on blood pressure (homeostasis model). System Dynamics is an exemplary tool for the development of materials consistent with National Science Education Standards. SD was specifically developed to emphasize interactions among system structure, organization, and behavior. Students use these material as part of inquiry-based science programs in which the teacher serves as a guide and facilitator rather than the primary source of all content information; technical writing by students is also encouraged. Finally, these SD materials will provide a coherent body of work to guide the ongoing professional development of the classroom science teacher.
Field trips to science museums can provide students with educational experiences, particularly when museum programs emphasize scientific inquiry skill building over content knowledge acquisition. We describe the creation and study of 2 programs designed to significantly enhance students' inquiry skills at any interactive science museum exhibit without the need for advanced preparation by teachers or chaperones. The programs, called Inquiry Games, utilized educational principles from the learning sciences and from visitor studies of museum field trips. A randomized experimental design compared
The Massachusetts Linking Experiences and Pathways Follow-on (M-LEAP2) is a three-year longitudinal empirical research study that is examining prospectively how early formal and informal STEM education experiences are related to gender-based differences in STEM achievement-related choices in middle and high school. M-LEAP2 serves as a complement to - and extension of - a prior NSF-funded study, M-LEAP, which was a largely quantitative research study that followed overlapping cohorts of 3rd - 6th grade female and male students for three years. M-LEAP surveyed over 1,600 students, 627 student-parent pairs, and 134 second parents in 8 diverse public schools across Massachusetts. In contrast, M-LEAP2 is a heavily qualitative three-year study using in-depth interviews with a diverse range of 72 of these students and their families to study how formal and informal science experiences shape the students' science-related beliefs, interests, and aspirations as they progress though middle and high school.
In this article Bell, Tzou, Bricker, and Baines describe how formal and informal educational experiences can merge through three case studies of youth engaged in science and technology. The theory of “cultural learning pathways” reframes our understanding of how, why, and where people learn over time and across spaces that have varying cultural values, everyday practices, and hierarchies of privilege and marginalization.
The adoption of the Next Generation Science Standards means that many educators who adhere to model-based reasoning styles of science will have to adapt their programs and curricula. In addition, all practitioners will have to teach modeling, and model-based reasoning is a useful way to do so. This brief offers perspectives drawn from Lehrer and Schauble, two early theorists in model-based reasoning.
This literature review raises questions about how scientific argumentation is taught in schools. Manz argues that argumentation needs to be situated in real scientific questions and practices and makes suggestions for how to make argumentation an authentic science activity for students.
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TEAM MEMBERS:
Sara Heredia
resourceresearchProfessional Development, Conferences, and Networks
In this research article, Allen and Penuel investigate how science teachers make decisions about implementation of reform based on their understanding of coherence between professional development and the standards, curriculum and assessment in their local context. This research will support ISE that design and facilitate science teacher professional development.
This Barron and Bell article provides a foundational overview for how “cross-setting learning” can equitably engage all youth across formal and informal educational contexts. The paper offers: 1) a review of research; 2) descriptions of supports and challenges to cross-setting learning, including learner interest and identity; and 3) suggestions for research and assessments that capture learning for underrepresented youth.
Educators in informal science are exploring data visualization as a way to involve learners in analyzing and interpreting data. However, designing visualizations of data for learners can be challenging, especially when the visualizations show more than one type of data. The Ainsworth three-part DeFT framework can help practitioners design multiple external representations to support learning.
Vossoughi and Bevan (2014) conducted a literature review of educational research on making and tinkering. They considered what was known about learning opportunities for young people afforded by high-quality tinkering and making experiences. Specifically they reviewed the historical roots of making, the emerging design principles that characterized tinkering and making programs, the pedagogical theories and practices that lead to supportive and collaborative learning environments, as well as the possibilities and tensions associated with equity-oriented teaching and learning.
Having developed the concept of near-peer mentorship at the middle school/high school level and utilized it in a summer science education enhancement program now called Gains in the Education of Mathematics and Science or GEMS at the Walter Reed Army Institute of Research (WRAIR), it is now our goal to ultimately expand this program into an extensive, research institute-based source of young, specially selected, near-peer mentors armed with kits, tools, teacher-student developed curricula, enthusiasm, time and talent for science teaching in the urban District of Columbia Public Schools (specific schools) and several more rural disadvantaged schools (Frederick and Howard Counties) in science teaching. We describe this program as a new in-school component, involving science clubs and lunch programs, patterned after our valuable summer science training modules and mentorship program. Our in-house program is at its maximum capacity at the Institute. Near-peer mentors will work in WRAIR's individual laboratories while perfecting/adapting hands-on activities for the new GEMS-X program to be carried out at McKinley Technology HS, Marian Koshland Museum, Roots Charter School and Lincoln Junior HS in DC, West Frederick Middle School, Frederick, MD and Folly Quarter Middle School and Glenelg HS, in Howard County, MD. Based on local demographics in these urban/rural areas, minority and disadvantaged youth, men and women, may choose science, mathematics, engineering and technology (SMET) careers with increasing frequency after participating, at such an early age, in specific learning in the quantitative disciplines. Many of these students take challenging courses within their schools, vastly improve their standardized test scores, take on internship opportunities, are provided recommendations from scientists and medical staff and ultimately are able to enter health professions that were previously unattainable. Relevance to Public Health: The Gains in the Education of Mathematis and Science (GEMS) program educates a diverse student population to benefit their science education and ultimately may improve the likelihood of successfully entry into a health or health-related professions for participating individuals. Medical education has been show to improve public health.