When it comes to STEM education, the nation’s K–12 public schools cannot do it all. The nature of 21st century proficiency in science, technology, engineering, and mathematics is too complex for any single institution. The good news is that schools do not have to do it alone. Museums, zoos, nature centers, aquariums, and planetariums are among the several thousand informal science institutions in the United States that regularly engage young people in observing, learning, and using STEM knowledge and skills. Providing a richness of resources unavailable in any classroom, informal science
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This article provides firm evidence, for formal and informal educators alike, that shared learning can be powerful and meaningful, if carefully considered. Findings from a study conducted in a summer middle school mathematics class suggest that when students are able to ask legitimate, authentic questions and share understanding about a common problem, their learning becomes truly “distributed by design.”
Teachers’ and learners’ gestures while giving explanations in mathematics can be categorized into three types, revealing their cognitive nature and communicative purpose: pointing reflects a grounding in the physical environment, representational gestures reveal mental simulations of action and perception, and metaphoric gestures reveal conceptual metaphors grounded in the physical human experience. Informal educators should reflect on their own gestures and those of learners, considering what they may contribute to greater learner understanding.
To create more equitable learning opportunities for students from marginalized communities, educators can design learning experiences that help young people connect their everyday interests and knowledge to academic content. Nasir et al. synthesized research on how students use sophisticated math in everyday practices like discussing basketball, playing dominoes, and selling candy. Then they explain how learning improves when varied student experiences are made relevant in informal and formal learning environments.
This article discusses the potential for learner engagement in the contexts of a basketball team and a mathematics classroom. The qualitative analysis centers on three aspects of each context: access to the domain, the integral roles available to learners, and opportunities for self-expression.
This article discusses intellectual activities in African American culture that privilege mathematical thinking. It is a helpful reference for educators and researchers who want to shift from deficit-oriented perspectives about non-dominant or marginalized groups’ performance to additive perspectives that build on out-of-school cultural knowledge and practices to support student learning in school. The authors suggest how educators might value forms of mathematical thinking that are usually not recognized in school. This recognition can support diverse students’ participation and achievement
Researchers Jurow, Hall, and Ma examined how conversations and interactions between students and STEM professionals expanded students’ understanding of math modeling.
There can be a mistaken impression that the new vision for K-12 science education is only relevant to classroom science instruction. But youth frequently engage in powerful science and engineering activities that take place after or outside-of-school. They learn STEM content, engage in STEM practices, and develop an understanding of how STEM is used in the world. To capitalize on those assets, educators and other stakeholders should learn about, leverage, and broker connections for youth across the STEM learning experiences available in and out of school.