The overall goal of the current proposal is to adapt the interdisciplinary research-based curriculum created at the School for Science and Math at Vanderbilt (SSMV) for implementation of a four-year program in three Metropolitan Nashville Public School (MNPS) high schools. The specific aims of the proposal are to adapt the on-campus (at Vanderbilt) model for implementation in three public high schools with different academic profiles (SSM Academies); to define the variables and features required to sustain the program and to replicate the model in any high school setting; and to define a strategy for disseminating the model to additional schools. Students entering 9th grade in a school in which an SSM Academy has been implemented will be encouraged to apply. Those who are accepted into the program will spend three hours every other day in two courses based on the adapted curriculum. As with the SSMV, rising seniors will have opportunities to enter Vanderbilt laboratories for summer research internships. Teachers from the high school will work with Center for Science Outreach scientists to adapt the SSMV curriculum for implementation. Ongoing, year-long teacher professional development will be conducted to ensure that the curriculum is dynamic and the teachers are well-prepared to engage and guide the students in the curriculum. The anticipated outcomes include enhanced student achievement as measured by GPA, and scores on ACT science reasoning and end of course tests; increased SSM student interest in careers in science; increased district-wide enrollment in SSM programs; increased graduation rates and postsecondary education enrollment by SSM students; development of unique curricular science units that can be adapted for a novel four-year interdisciplinary research- based curriculum; development of a sustainable model built on effective features of each SSM that can be exported to other high schools within and outside Nashville; enhanced community and family involvement in the SSM programs and school community in general; a strengthened partnership between Vanderbilt and MNPS that will serve as a national model of a successful university-K-12 collaboration to enhance science teaching and learning.
Through "Addressing the Science of Really Gross Things: Engaging Young Learners in Biomedical Science Through a Fulldome Planetarium Show and Supporting Curricula," Morehead Planetarium and Science Center at the University of North Carolina at Chapel Hill, in close collaboration with NIH-funded researchers at the UNC and a leading children's book author, will develop an informal science education media project and a suite of hands-on, inquiry-based curricula based on the media project for use in science centers, museums and schools. This project will build the pipeline of future researchers and create awareness of NIH-funded research by generating interest and excitement among children age 9-13 in the health sciences and related careers and building their science content knowledge. To achieve the objective, the investigators will develop a fulldome planetarium show; create correlating curricula for summer camps, afterschool programs, scout programs, science center field trips, science clubs and schools; and produce a DVD highlighting careers in the health sciences. In addition, the project will use several methods to target populations traditionally underrepresented in the biomedical fields, including featuring professionals from underrepresented populations in the multimedia and curricula products, making outreach visits to counties with large populations traditionally underrepresented in health science research careers, and producing a Spanish-language version of the products. The use of a known brand, "Grossology," is an innovative way to connect to children in the target age range and to encourage the informal science education community to embrace health-science content in their fulldome theaters. In addition, the project's hub-and-spoke approach further encourages adoption of this programming by providing informal science venues with both an engaging experience (hub) and the supporting curricula (the spokes) that is necessary to extend the show's potential for having significant educational impact. A strong project team maximizes the project's likelihood for success. The team includes fulldome producers and educators from Morehead and NIH-funded researchers with expertise in appropriate science content areas. In addition, the investigators have created a network of consultants, advisory board members and evaluators that will create feedback loops designed to ensure high-quality, scientifically-accurate, educationally-effective products. The investigators will use a combination of free and revenue-based dissemination strategies to ensure that the products of this award are broadly distributed. These strategies hold significant promise for creating broad use of this project's products in the nation's science centers, museums and classrooms.
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.
Researchers Jurow, Hall, and Ma examined how conversations and interactions between students and STEM professionals expanded students’ understanding of math modeling.
What is the relationship between experiences in informal settings and students’ understanding of and attitudes toward science? By analysing existing data sets, Suter finds that science museum attendance has an effect—albeit a small one—on student achievement.
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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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.
The field of informal science education has embraced “making” and design activities as a powerful approach to engaging learners. This chapter by Blikstein finds that in order to create disruptive spaces where students can learn STEM, design and build inventive projects, educators . This paper provides theoretical background and concrete cases that illuminate program design and implementation issues related to making.
This Stocklmayer, Rennie, and Gilbert article outlines current challenges in preparing youth to go into science careers and to be scientifically literate citizens. The authors suggest creating partnerships between informal and formal education to address these challenges in school.
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.