Stephanie Spiris is a 12-year veteran teacher at George Washington High School in Denver, teaching courses in biomedical science (Figure 1). Last year, Spiris spent four weeks in a summer internship at Terumo BCT, a medical device company that focuses on blood processing for medical treatment and care. Decked in full lab gear and ready to learn, Spiris worked in a sterile lab, conducting projects that allowed her firsthand experience with tasks such as separating t-cells from blood and freeze-drying plasma.
The Center for the Advancement of Informal Science Education defines informal STEM education as “lifelong learning in science, technology, engineering, and math (STEM) that takes place across a multitude of designed settings and experiences outside of the formal classroom.” The design of an informal experience can vary widely. On one end of the spectrum are free-choice learning experiences, where participants determine what they want to learn, when they want to do it, and how and with whom they want to study. On the opposite end of the spectrum is nonformal learning, which includes any
The Discovery Research K-12 program (DRK-12) seeks to significantly enhance the learning and teaching of science, technology, engineering and mathematics (STEM) by preK-12 students and teachers, through research and development of innovative resources, models and tools (RMTs). Projects in the DRK-12 program build on fundamental research in STEM education and prior research and development efforts that provide theoretical and empirical justification for proposed projects.
STEM Practice-rich Investigations for NGSS Teaching (SPRINT) is an exploratory project that will research and develop resources and a model for professional learning needed to meet the demand of implementing the Next Generation Science Standards (NGSS). The Exploratorium Teacher Institute will engage middle school science teachers in a one-year professional learning program to study how familiar routines and classroom tools, specifically hands-on science activities, can serve as starting points for teacher learning. The Teacher Institute will use existing hands-on activities as the basis for developing "practice-rich investigations" that provide teachers and students with opportunities for deep engagement with science and engineering practices. The results of this project will include: (1) empirical evidence from professional learning experiences that support teacher uptake of practice-rich investigations in workshops and their classrooms; (2) a portfolio of STEM practice-rich investigations developed from existing hands-on activities that are shown to enhance teacher understanding of NGSS; and (3) a design tool that supports teachers in modifying existing activities to align with NGSS.
SPRINT conjectures that to address the immediate challenge of supporting teachers to implement NGSS, professional learning models should engage teachers in the same active learning experiences they are expected to provide for their students and that building on teachers' existing strengths and understanding through an asset-based approach could lead to a more sustainable implementation. SPRINT will use design-based research methods to study (a) how creating NGSS-aligned, practice-rich investigations from teachers' existing resources provides them with experiences for three-dimensional science learning and (b) how engaging in these investigations and reflecting on classroom practice can support teachers in understanding and implementing NGSS learning experiences.
The Exploratorium Teacher Institute (TI) is a teacher professional development center that offers comprehensive, multiyear professional learning institutes; classroom coaching and mentoring; and teaching tools to middle and high school science teachers. The TI staff is composed of a team of PhD scientists and veteran secondary science educators who work in concert to provide teachers with resources and experiences that develop the content knowledge and pedagogical skills necessary for teaching authentic science content through student-centered activities (McDermott and DeWater 2000). All of
As a leader in the science museum field, the New York Hall of Science (NYSCI) is a destination for hands-on, interactive exhibitions and innovative programs. NYSCI’s Design-Make-Play (DMP) pedagogical approach to STEM learning recognizes that what is essential is not only the content—what is being taught—but how teaching and learning are imagined through the curriculum. This commitment to practice builds off of interest-based learning research, which emphasizes that all learners should feel a sense of efficacy and possibility. The hallmarks of this approach include deep personal engagement
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TEAM MEMBERS:
Amanda SolarshGina TesorieroMichaela LabrioleTara Chudoba
National Air and Space Museum, Washington DC
Summative Evaluation for Educational Program, 2016
The National Air and Space Museum (NASM) contracted Randi Korn & Associates, Inc. (RK&A) to conduct a summative evaluation of Science in Pre-K, an onsite and online teacher professional development program that NASM developed for the District of Columbia Public Charter Schools’ (DCPS). The program supports preschool teachers in teaching science through exploration and problem solving. This evaluation is a continuation of a planning and evaluation project initiated in 2013. In 2013, RK&A
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?
The fields of science education and science communication share the overarching goal of helping non-experts and non-members of the professional science community develop knowledge of the content and processes of scientific research. However, the specific audiences, methods, and aims employed in the two fields have evolved quite differently and as a result, the two fields rarely share findings and theory. Despite this lack of crosstalk, one theoretical construct—framing—has shown substantial analytic power for researchers in both fields. Specifically, both fields have productively made use of
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
In the 1920s, John Dewey and Walter Lippmann both wrote important books examining whether the public was capable of playing a constructive role in policy, particularly when specialized knowledge was involved. This essay uses the Lippmann–Dewey debate to identify new challenges for science education and to explore the relationship between science education and science communication. It argues that science education can help foster democracy in ways that embody Habermas' ideal of the public sphere, but only if we as a field pay more attention to (1) the non-scientific frames and narratives that
In some senses, both science education and science communication share common goals. Both seek to educate, entertain and engage the public with and about science. Somewhat surprisingly, given their common goals, they have evolved as disparate academic fields where each pays little attention to the other.1 The purpose of this special issue, therefore, is an attempt some form of rapprochement—to contribute to building a better awareness of what each has to contribute to the other and the value of the scholarship conducted in both fields.
PEEP and the Big Wide World/El Mundo Divertido de PEEP is a bilingual, NSF- funded public media project that uses animation, live-action videos, games, mobile apps, hands-on science activities to motivate preschool-age children to investigate the world around them. Online, PEEP extends children’s science and math learning with a mobile-friendly website that offers games, videos, and hands-on activities, as well as a collection of 15 apps. PEEP is also reaching children in preschool classrooms and family/home childcare settings via the PEEP Science Curriculum, which provides resources for a