The Discovery Center at Murfree Spring, in partnership with six science centers and museums, will promote and invest in science education in rural communities with limited museum access. This coalition will work with two cohorts of rural school communities (12 total) and focus on engaging, learning from, and supporting rural school districts, teachers, families, and communities through relationship building, asset mapping, and the collaborative integration and implementation of museum resources. Additional activities include the production of publications, virtual presentations, and a virtual tool kit. The project will illustrate the ways in which museums can collaborate to support STEM and literacy at the K-2 level, enhance teacher self-efficacy, attitudes and beliefs, and engage family and community, strengthening services for Americans who live in the most rural areas.
The Jackson Hole Children’s Museum will expand its K–5th grade STEAM programs, which serve more than 1,300 students in Teton County School District #1. The STEAM programs provide inquiry-based, hands-on programming to all K–5 District students in accordance with the Wyoming State Science Standards. An additional 500 students are reached through homeschool groups, summer school, childcare and therapy organizations, and nearby Idaho schools. Each two-hour program opens with interactive, student-centered, scientific method lab stations. Students are then challenged to use newly acquired vocabulary and knowledge to complete a hands-on building project. The program is designed to contribute to increasing science and engineering literacy in the community and to support the development of students’ 21st century skills.
The Pensacola MESS Hall will create and deliver “Science Sprouts”—a four-session classroom program for kindergarten students, including related professional development for teachers. The program will focus on 10 underserved elementary schools in the community, providing students and teachers access to quality math, engineering, and science experiences. Trained museum educators will engage children in hands-on exploration while engaging teachers in effective methods to enhance classroom learning. The lessons will include a story followed by small group activities that reinforce key concepts. To increase the teachers’ comfort in program delivery and application to other curricular units, the activities will utilize common materials and connect to children’s literature.
The Discovery Center, operated by the United States Space Foundation, will partner with the Pikes Peak Library District to implement Small Steps, Giant Leap: STEM Adventures for Little Space Explorers, a free early literacy program designed for children ages 3-6 that seeks to engage the target audience of low-income and military families, populations currently underserved by the Discovery Center. The program is an interactive storytelling experience with an associated hands-on craft that occurs twice monthly, once in person and once virtually, and is designed to enable early learners to grow in literacy via the lenses of science and space exploration while developing vital social skills and self-esteem.
The Discovery Center at Murfree Spring will partner with Mid-Cumberland Head Start to launch the SPARK! Head Start program to reach under-resourced early learners, families, and teachers in Rutherford County, Tennessee. Building on its successful STEM programming that integrates science with children's books, the museum will increase connections between science and literacy skills for 132 pre-K children ages three to five, and enhance the capacity of 16 teachers and two administrators within Rutherford County. Head Start will integrate and embed literacy and science process skills through hands-on STEM activities linked to children's literature and best practices. The project will also include programming designed to increase family engagement in STEM at the museum and at partnering Head Start centers.
Student engagement is an important predictor of choosing science-related careers and establishing a scientifically literate society: and, worryingly, it is on the decline internationally. Conceptions of science are strongly affected by school experience, so one strategy is to bring successful science communication strategies to the classroom. Through a project creating short science films on mobile devices, students' engagement greatly increased through collaborative learning and the storytelling process. Teachers were also able to achieve cross-curricular goals between science, technology
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TEAM MEMBERS:
Kaitlyn MartinLloyd DavisSusan Sandretto
This Masters project consists of two elements: 1) an integrated after-school program to improve student English language reading and academic outcomes for third graders' vocabulary development by incorporating music, artistic creativity and linguistics; 2) a pilot sample curriculum that demonstrates the approach for building student comprehension through musical theater and Science, Technology, Engineering, and Mathematics (STEM) content experiences. Called "Water Buddy", this is an after-school program uses singing, dancing, writing, and play to build reading and vocabulary skills. The goal
As part of its overall strategy to enhance learning in informal environments, the Advancing Informal STEM Learning (AISL) program seeks to advance new approaches to, and evidence-based understanding of, the design and development of STEM learning in informal environments. This includes providing multiple pathways for broadening access to and engagement in STEM learning experiences, advancing innovative research on and assessment of STEM learning in informal environments, and developing understandings of deeper learning by participants. This project would expand the informal STEM learning field's understanding of how to use digital science media to increase STEM educational experiences and opportunities for English language learners. Across the U.S. there are significant STEM opportunity and achievement gaps for English learners with varying levels of English proficiency. This is at a time when the U.S. is facing a shortage of STEM professionals in the workforce including the life and physical science fields. This project aims to close these gaps and improve English learners' STEM learning outcomes using digital media. Within community colleges, there are multiple site-based programs to provide content to help English learners to learn English and to improve their math and literacy skills. Involving the state community college networks is a critical strategy for gathering important feedback for the pedagogical approach as well as for recruiting English learner research participants. The team will initially study an existing YouTube chemistry series produced by Complexly then produce and test new videos in Spanish using culturally relevant instructional strategies. The target audience is 18-34-year-old English learners. Project partners are Complexly, a producer of digital STEM media and EDC, a research organization with experience in studying informal STEM learning.
The project has the potential to advance knowledge about the use of culturally relevant media to improve STEM opportunities and success for English language learners. Using a Design-Based Implementation Research framework the research questions include: 1) what are the effective production and instructional strategies for creating digital media to teach science to English learners whose native language is Spanish? 2) what science content knowledge do English learners gain when the project's approach is applied to a widely available set of YouTube videos? and 3) how might the findings from the research be applied to future efforts targeting English learners? The project has the potential to significantly broaden participation in science and engineering. Phase 1 of the research will be an exploration of how to apply strategic pedagogical approaches to digital media content development. Interviews will be conducted with educators in 3 focal states with high numbers of English language learners (NY, CA, TX) to reflect on pedagogical foundations for teaching science to English learners. A survey of 30 English learners will provide feedback on the perceived strengths and weaknesses of a selection of existing YouTube chemistry videos. Phase 2 will create/test prototypes of 6 adapted chemistry videos. Forty students (ages 18-34) will be recruited and participate in cognitive interviews with researchers after viewing these videos. Based on this input additional videos will be produced with revised instructional strategies for further testing. Additional rounds of production and testing will be conducted to develop an English learners mini chemistry series. Phase 3 will be a pilot study to gauge the science learning of 75 English learners who will view an 11-episode chemistry miniseries. It will also identify gaps in expected learning to determine whether any further adjustments are necessary to the instructional approach.
This Innovations in Development award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.
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TEAM MEMBERS:
Kelsey SavageCeridwen RileyStan MullerHeather LavigneCaroline ParkerKatrina Bledsoe
Future educational robots are emerging as social companions supporting learning. By socially interacting with such a robot, learners can potentially reason and talk about the things they are learning and receive help in seeing the relevance of STEM in their daily lives. However, little is known about how to design educational robots to work with youth at home over a long period of time. This project will develop an informal science learning program, called STEMMates, in collaboration with a local community center, for youth with little interest in science. The program will partner learners with an in-home learning companion robot, designed to read books with youth and provide science activities for them at the community center, where youth will engage in exciting and personally relevant science learning. As the learner reads books, the robot will make comments about what is happening in the book to help connect the reading to the science activities at the community center. The overarching goals of STEMMates are to: (a) positively support youth's individual interest in science and future science learning, (b) connect in-home learning experiences with out-of-school community-based learning, (c) bridge the gap between formal and informal engagement and learning in science, and (d) encourage the participation of youth who are underrepresented and who have low interest in STEM learning. This project is funded by the Advancing Informal STEM Learning program, which seeks to advance new approaches to and evidence-based understanding of the design and development of STEM learning opportunities for the public in informal environments.
Researchers will work with youth and staff at the community center, alongside experts in informal science learning, to design the program and then test how learners respond to reading with the robot and participating in the science activities and whether this program has a lasting impact on their science interest. Social interactions with a robot may help distribute cognitive load during learning activities to help youth reason about STEM and also supplement learning by improving feelings of value and belongingness in order to facilitate lasting interest development. Following a mixed-methods research approach using qualitative and quantitative data-collection techniques, the research team will investigate the following research questions: (1) What social and interest-development supports and activities can be utilized as socially situated interest scaffolds in an informal and in-home, augmented reading and science activity program to promote individual interest and learning in science for low interest learners? How can a social robot best facilitate this program? (2) How do learners perceive and interact with the robot in authentic, in-home, long-term situations, and how does this interaction change over time? (3) Does working with a robot designed with socially situated interest scaffolds increase individual interest in science when compared to a pre-intervention baseline, and do these effects impact future (long-term) interest and engagement in formal science learning? To answer these research questions, researchers will implement the science learning program during an 11-week summer deployment and utilize an AB single-case research design. Interview-based qualitative data and self-report surveys to examine the learner?s perception of the robot and their evolving interest in science and quantitative data on science learning using pre-/post-measure comparisons will be collected. Log data of time-on-task, reading rate, book selection and reading goal attainment will also be collected by the robot. The outcomes of this project will lay the groundwork for future investigations of the design of social robots for a diversity of learner populations and their use in different informal learning settings.
This project is funded by the National Science Foundation's (NSF's) Advancing Informal STEM Learning (AISL) program, which supports innovative research, approaches, and resources for use in a variety of learning settings.
In the United States, broad study in an array of different disciplines —arts, humanities, science, mathematics, engineering— as well as an in-depth study within a special area of interest, have been defining characteristics of a higher education. But over time, in-depth study in a major discipline has come to dominate the curricula at many institutions. This evolution of the curriculum has been driven, in part, by increasing specialization in the academic disciplines. There is little doubt that disciplinary specialization has helped produce many of the achievement of the past century
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TEAM MEMBERS:
David SkortonAshley BearNational Academies of Sciences, Engineering, and Medicine
Many people believe that both public policy and personal action would improve with better access to “reliable knowledge about the natural world” (that thing that we often call science). Many of those people participate in science education and science communication. And yet, both as areas of practice and as objects of academic inquiry, science education and science communication have until recently remained remarkably distinct. Why, and what resources do the articles in this special issue of JRST give us for bringing together both the fields of practice and the fields of inquiry?
Recent decades have seen an increasing emphasis on linking the content and aims of science teaching to what the average citizen requires in order to participate effectively in contemporary society, one that is heavily dependent on science and technology. However, despite attempts to define what a scientific education for citizenship should ideally involve, a comprehensive set of key aspects has yet to be clearly established. With this in mind, the present study sought to determine empirically the extent of any consensus in Spain regarding the principal aspects of scientific competence that
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TEAM MEMBERS:
Angel Blanco-LopezEnrique Espana-RamosFrancisco Jose Gonzalez-GarciaAntonio Joaquin Franco-Mariscal